JP4961262B2 - Endoscope system - Google Patents

Description

  The present invention relates to an endoscope system that prevents a used endoscope from being reused as it is.

  In a general endoscope, for example, an objective lens that is an observation optical system is disposed at a distal end configuration portion that is disposed at the distal end of an insertion portion that is inserted into a body cavity during examination. When the insertion portion is inserted into the body cavity, mucus or the like in the body cavity adheres to the objective lens, and the visual field may be disturbed. In such a case, when the air supply button or the water supply button of the operation part of the endoscope is pushed in, for example, a fluid such as air or cleaning water is provided inside the insertion part. It is supplied to the nozzle provided in the tip constituent part via the path. As a result, it is general that the fluid is sprayed from the nozzle onto the surface of the objective lens to remove mucus or the like adhering to the objective lens.

Patent Document 1 includes a detection unit that detects a state in which the endoscope is not used, and when a state in which the endoscope is not used is detected, an illumination light source or an imaging system is detected based on a signal output from the detection unit. A configuration for saving energy by automatically turning off the drive power source is shown.
Japanese Patent Application Laid-Open No. 08-122654

  Usually, the insertion portion of the endoscope that has been used once inserted into the body cavity is removed from the body cavity and then cleaned and disinfected. As a newly used endoscope, either a cleaned and disinfected endoscope or a new endoscope is used. However, in the conventional endoscope system, there is no special means for determining whether the endoscope to be newly used is an unused endoscope or a used endoscope. The endoscope may be reused as it is.

  In the endoscope of Patent Document 1 described above, it is determined that the endoscope is used by detecting camera shake when gripping the endoscope, and when the camera shake is not detected, the endoscope is not used. Deciding. However, the endoscope of Patent Document 1 does not prevent a used endoscope from being reused (inserted) into a body cavity without being cleaned and disinfected. Cannot be reused as is.

  The present invention has been made in view of such circumstances, and an object thereof is to provide an endoscope system that can prevent a used endoscope from being reused as it is.

In order to achieve the object, the present invention provides a detection unit that detects a state in which a fluid flows in a conduit disposed in an endoscope, and a detection unit that is provided in the endoscope and that is used in the endoscope. Connected to a use state storage unit whose storage state changes according to the presence or absence, the detection unit and the use state storage unit, and based on the detection result output from the detection unit, whether or not the endoscope is used A control unit that determines and changes a storage state of the use state storage unit, and the control unit is in a state in which the endoscope is in use based on a detection result output from the detection unit. When it is determined that the endoscope is stopped after a set time set in advance as desired, or when it is determined from the state of the use state storage unit that the endoscope is in use be characterized by the chromatic endoscopic stopping means for stopping the endoscope To provide an endoscopic system.

  ADVANTAGE OF THE INVENTION According to this invention, the endoscope system which can prevent that the used endoscope is reused as it is can be provided.

A first embodiment according to the present invention will be described with reference to FIGS.
FIG. 1 is a schematic configuration diagram of an endoscope system according to the present embodiment. FIG. 2 is a schematic configuration diagram showing an arrangement state of each pipe line arranged in the endoscope system. FIG. 3 is a schematic view showing an air supply conduit. FIG. 4 is a diagram illustrating a control configuration of the endoscope system. FIG. 5 is a diagram showing current values when the air / water pump is driven. FIG. 6 is a flowchart illustrating an operation method according to the first embodiment.

  As shown in FIG. 1, the endoscope system 1 is provided with an endoscope (hereinafter, scope unit) 3 and a light source device 72 connected to the scope unit 3. The scope unit 3 includes an elongated insertion portion 2 that is inserted into a body cavity of a patient, and an operation portion 4 that is connected to a proximal end located on the proximal side of the insertion portion 2 and operates the insertion portion 2.

  One end of a universal cord 6 is connected to the operation unit 4. At the other end of the universal cord 6, a connector 8 for connection with an external device is provided. The scope unit 3 is connected to the light source device 72 and the video processor 82 through the connector 8. This connector 8 is detachable from the light source device 72 and the video processor 82.

  The insertion portion 2 includes an elongated flexible tube portion 10 in which the operation portion 4 and the base end portion are connected, a bending portion 12 in which the base end portion is connected to the distal end of the flexible tube portion 10, and the bending portion 12. A distal end rigid portion 14 having a proximal end portion connected to the distal end is provided.

  For example, an illumination lens of an illumination optical system (not shown), an objective lens of an observation optical system, and a fluid (for example, gas (air) 61 or liquid from the distal surface as shown in FIG. 62), the air supply / water supply nozzle 16, the distal end opening 18 of the treatment instrument insertion channel 44, and the like are disposed. The treatment instrument insertion channel 44 also serves as a suction conduit for sucking fluid from the distal end surface.

  The air / water supply nozzle 16 in this embodiment cleans, for example, the above-described illumination lens, objective lens of the observation optical system, and the like by flowing a fluid into the body cavity. Such washing is performed in order to remove the mucus in the body cavity attached to the illumination lens and the objective lens of the observation optical system and secure a visual field when the insertion unit 2 is inserted into the body cavity. The suction conduit sucks fluid from the body cavity. Thus, the air / water supply nozzle 16 and the suction pipe are used when the insertion portion 2 is inserted into the body cavity.

  In the distal end rigid portion 14, an air / water feeding tube 16 a is connected to the air / water feeding nozzle 16, and a suction tube 24 is connected to the distal end opening 18. A part of the suction tube 24 also serves as the treatment instrument insertion channel 44. The air / water supply tube 16 a is divided into two portions of the air supply tube 20 and the water supply tube 22 in the bending portion 12. The air supply tube 20, the water supply tube 22, and the treatment instrument insertion channel 44 are inserted through the bending portion 12 and the inside of the flexible tube portion (serpentine tube portion) 10 to the operation portion 4.

  A distal end portion of a light guide fiber (not shown) is fixed to the distal end rigid portion 14 behind the illumination lens. Further, an imaging element such as a CCD and its connection circuit board are fixed behind the objective lens. In addition, it may replace with an image pick-up element, the tip part of the image guide fiber which is not shown in figure may be fixed, and the scope unit 3 is not limited to an electronic scope but may be a fiber scope.

  The operation unit 4 is provided with a grip 28 that is held by an operator. A base end portion of the universal cord 6 is connected to the grip portion 28. The air supply tube 20, the water supply tube 22, and the suction tube 24 described above communicate with the connector 8 through the universal cord 6.

  Further, the grip 28 includes an up / down bending operation knob 32 for bending the bending portion 12 up and down, a left / right bending operation knob 34 for bending the bending portion 12 left and right, and a suction activation unit for starting a suction pump 70 described later. A suction button 36, an air / water feed button 38, which is an air / water feed starting unit for starting an air / water feed pump 71 described later, various buttons 40 for endoscopic photography, and a treatment instrument insertion unit 42. Are provided. The air / water supply button 38 may be provided separately for air supply and water supply. The treatment instrument insertion portion 42 is provided with a treatment instrument insertion port (forceps port) 48 connected to a proximal end portion of a treatment instrument insertion channel 44 disposed in the insertion portion 2. The distal end of the treatment instrument insertion channel 44 communicates with the suction tube 24 as shown in FIG. An endoscope treatment tool (not shown) is inserted from the treatment tool insertion port 48 of the endoscope system 1 into the treatment tool insertion channel 44 and the suction tube 24, and is pushed into the distal rigid portion 14 side. Thereafter, the endoscope treatment tool is projected outside from the distal end opening 18 of the treatment tool insertion channel 44.

  The connector 8 includes a ground terminal 50 for collecting leakage current at the time of high frequency treatment, a water supply base 54 for connecting the water supply tube 22 to the water supply tank 52 as shown in FIG. An air supply base 58 that communicates with the suction pump 60 and a suction base 60 that communicates the suction tube 24 with the suction pump 70 are provided. The air supply tube 20 is divided into two forks. One communicates with the water supply tank 52 via the air supply base 58, and the other communicates with the air supply pipe 56.

  The water supply tank 52 is filled with a liquid 62 and is a transparent container made of, for example, resin. Therefore, the filling amount of the liquid 62 filled with the eye can be easily confirmed. The water supply tank 52 is provided with a scale 66 that is a measuring unit 64 for measuring the liquid 62. The measuring unit 64 checks the liquid level that moves (decreases) in proportion to the amount of administration (consumption, supply) of the liquid 62 by the scale 66, thereby reducing the remaining amount of the liquid 62 held in the water supply tank 52. It is a remaining amount measuring unit for measuring. Instead of the scale 66, for example, a liquid level detection sensor that detects the level of the liquid 62 held in the water supply tank 52 may be used to measure the dose of the liquid 62.

  A stopper 68 is provided at the upper part of the water supply tank 52. The plug 68 substantially seals the water supply tank 52 so that the liquid 62 does not leak. The water supply tube 22 passes through the plug 68. The material of the plug 68 is a material that does not affect the liquid component, and is made of, for example, rubber. The water supply tube 22 extends to the vicinity of the bottom surface of the water supply tank 52.

  The connector 8 is connected to the light source device 72. Thereby, the air supply pipe 56 is connected to the air / water supply pump 71 provided in the light source device 72, and the air 61 is supplied to the air supply pipe 56 by the air / water supply pump 71. When the connector 8 is connected to the light source device 72, the light guide connecting portion 75 provided on the connector 8 is also connected to the connector receiver 74.

  A predetermined number of contacts 76 for electrical connection with the light source device 72 are provided on the outer peripheral portion on the connection end side of the connector 8. Further, the connector 8 is provided with an electric connector portion 78 at an intermediate portion, and the electric connector portion 78 is connected to the video processor 82 via an electric cable 80. The video processor 82 is connected to a monitor 84 as a display unit, and an image picked up by the objective lens described above is displayed on the monitor 84 and can be observed.

  An air supply / water supply pump 71, which is an air supply / water supply section, sends air 61 from the outside of the apparatus through the air supply tube 56, the air supply tube 20, the air supply / water supply tube 16a, and the air supply / water supply nozzle 16 to the body cavity Air in. As described above, the air supply tube 56, the air supply tube 20, the air / water supply tube 16a, and the air / water supply nozzle 16 form an air supply conduit for supplying air.

  The air / water pump 71 supplies air 61 to the water supply tank 52 via the air supply pipe 56 and the air supply tube 20, and pressurizes the water supply tank 52. As a result, the liquid 62 is supplied into the body cavity via the water supply tube 22, the air / water supply tube 16 a, and the air / water supply nozzle 16. The air / water pump 71 feeds the liquid 62 into the body cavity in this way. Thus, the air supply pipe 56, the air supply tube 20, the water supply tank 52, the air supply / water supply tube 16a, and the air / water supply nozzle 16 form a water supply conduit.

  A suction pump 70 serving as a suction unit sucks fluid from the body cavity through the distal end opening 18, the treatment instrument insertion channel 44, and the suction tube 24. Thus, the distal end opening 18, the treatment instrument insertion channel 44, and the suction tube 24 form a suction conduit.

  As described above, in the present embodiment, the conduit through which the fluid flows includes the air supply conduit for supplying the air 61 into the body cavity, the water supply conduit for supplying the liquid 62 into the body cavity, and the fluid from the body cavity. The air supply conduit, the water supply conduit, and the suction conduit are disposed inside the scope unit 3.

  The suction pump 70 and the air / water supply pump 71 are different constituent members. However, as long as the air 61 can be supplied to the body cavity, the liquid 62 can be supplied to the body cavity, and the fluid can be sucked from the body cavity. The same member may be used.

  As shown in FIGS. 2 and 3, a hole 92 is provided in the pressing portion 90 of the air / water supply button 38. As described above, when the air / water supply pump 71 supplies the air 61 into the body cavity, the hole 92 is blocked by, for example, the finger 94 or the like. In this state, the air supply tube 20 is opened and the water supply tube 22 is closed. Thus, as described above and as shown in FIG. 3, the air / water feed pump 71 uses the air 61 as the air feed pipe 56, the air feed tube 20, the air / water feed tube 16 a, and the air / water feed nozzle 16. Through the body cavity.

  When the air / water supply pump 71 supplies the liquid 62 into the body cavity, the air / water supply button 38 is pushed (pressed). Thereby, the air supply tube 20 is closed and the water supply tube 22 is opened. The air / water supply pump 71 supplies air 61 to the air supply tube 20 via the air supply pipe 56. At that time, since the air supply tube 20 is closed by the air supply / water supply button 38, the air 61 is supplied to the water supply tank 52 via the air supply tube 20 and the water supply tube 22. Since the water supply tank 52 is substantially sealed by the stopper 68, when the air 61 flows in, the water supply tank 52 is pressurized. As a result, the air / water supply pump 71 supplies the liquid 62 filled in the water supply tank 52 into the body cavity via the water supply tube 22, the air / water supply tube 16 a, and the air / water supply nozzle 16.

  When the suction button 36 is pushed in, fluid is sucked from the body cavity via the distal end opening 18, the treatment instrument insertion channel 44, and the suction tube 24 by the suction force generated from the suction pump 70 as described above.

Next, the system configuration of the endoscope system 1 will be described with reference to FIG. As shown in FIG. 4, the scope unit 3 having the fuse 108 and the light source device 72 are connected. The light source device 72 includes an MPU 102 that controls the endoscope system 1 and the like, a detection unit 104, a switching unit 106, and an endoscope stop unit 110. The light source device 72 is provided with an air / water pump 71 connected to the detection unit 104. The endoscope stop unit 110 includes a warning unit 112 and a measurement unit 114. The MPU 102 is connected to the detection unit 104, the switching unit 106, the warning unit 112, and the measurement unit 114. The detection unit 104 is connected to the suction pump 70, and the warning unit 112 is connected to the monitor 84 via the video processor 82. The fuse 108 is provided, for example, in the connector 8 of the scope unit 3.
When the connector 8 of the scope unit 3 is connected to the light source device 72, the fuse 108 and the switching unit 106 on the light source device 72 side are connected.

The detection unit 104 measures the current value of the air / water pump 71, converts the measurement result into a signal state that can be received by the MPU 102, and transmits a signal having the measurement result to the MPU 102. Usually, when the air / water pump 71 is driven (fluid is fed into the body cavity or water is fed), the current value of the air / water pump 71 rises to a constant value as shown in FIG. The detection unit 104 detects such a change in the current value, and detects that the fluid has flowed into the pipe line based on the current value.
The MPU 102 receives the above-described signal transmitted from the detection unit 104, and determines whether or not the scope unit 3 is used based on this signal. The MPU 102 stores a threshold value for this determination, and performs various calculations when determining whether or not the scope unit 3 is used. The threshold value is a value with respect to the current value of the air / water pump 71 as shown in FIG.

  The MPU 102 transmits a control signal corresponding to the calculation result to the switching unit 106, switches the switch 106S, and changes the state of the fuse 108. In this way, the MPU 102 determines whether or not the scope unit 3 is used based on the detection result transmitted from the detection unit 104, and changes the state of the fuse 108.

  Further, the MPU 102 can receive a LOW or HIGH signal, which will be described later, from the switching unit 106, and can determine whether or not the scope unit 3 is used even from this signal. More specifically, since these signals are output according to the state of the fuse 108 described later, the MPU 102 can determine whether or not the scope unit 3 is used even from the state of the fuse 108.

When the MPU 102 determines that the scope unit 3 has been used, the MPU 102 transmits an instruction (signal) for starting time measurement to the measurement unit 114 and receives measurement time information from the measurement unit 114. The measurement time information is a measurement time measured by the measurement unit 114 or an information signal described later.
After the MPU 102 receives the measurement time information, the MPU 102 transmits usage status information (first warning to be described later) to the warning unit 112. The usage status information is, for example, information indicating that the scope unit 3 has started to be used or remaining time information. The remaining time information is a remaining time obtained by subtracting a measurement time from an inspectable time described later.

  When the measurement time reaches the inspection possible time (remaining time becomes 0), or when the used scope unit 3 is connected to the light source device 72, the MPU 102, for example, captures an image (hereinafter referred to as an objective lens). Usage status information (second warning to be described later) instructing not to display (endoscopic image) on the monitor 84 (end of the endoscope apparatus) is transmitted to the warning unit 112.

  The switching unit 106 includes a resistor R1 (signal reading resistor), a resistor R2 (signal writing resistor), and a changeover switch 106S. The resistance value of the resistor R1 is larger than the resistance value of the resistor R2. When the connector 8 and the light source device 72 are connected, the switching unit 106 connects the changeover switch 106S to the resistor R1 or the resistor R2, and switches the connection state between the fuse 108, the resistor R1, and the resistor R2.

By switching in this way, the switching unit 106 switches between the used signal reading mode (hereinafter referred to as reading mode) and the used signal writing mode (hereinafter referred to as writing mode).
The reading mode is that the fuse 108, the resistor R1, and a used signal input terminal (not shown) of the MPU 102 are conducted. When the scope unit 3 is not used, the changeover switch 106S holds the fuse 108 and the resistor R1 in a connected state (the changeover unit 106 switches to the reading mode). At this time, since the power source (not shown) of the switching unit 106 passes a current having a small value through the fuse 108, the fuse 108 is held without being cut. In the reading mode, a LOW signal is output to the MPU 102.
In the write mode, the fuse 108 and the resistor R2 are brought into conduction. The resistor R2 can pass a current sufficient to blow the fuse 108. When the scope unit 3 is in use, the changeover switch 106S is switched by a control signal corresponding to the calculation result of the MPU 102. Thereby, the changeover switch 106S holds the fuse 108 and the resistor R2 in a connected state (the changeover unit 106 switches to the write mode). At this time, a power source (not shown) of the switching unit 106 causes a current having a large value to flow through the fuse 108 to cut the fuse 108.
At this time, a HIGH signal is output to the MPU 102.

  At this time, the changeover switch 106S is switched and connected to the resistor R1 (the switching unit 106 switches to the reading mode). Once a HIGH signal is output to the MPU 102, no large current flows through the fuse 108 as long as the scope unit 3 is connected to the light source device 72. Therefore, since the changeover switch 106S is not connected to the resistor R2, the reading mode is maintained instead of the writing mode.

  As described above, the fuse 108 stores the state of whether or not the scope unit 3 is used based on the control signal output from the MPU 102, and the storage state (cut state) changes depending on whether or not the scope unit 3 is used. It is a state storage unit.

When the fuse 108 is conductive, a LOW signal indicating the usage status of the fuse 108 is input from the switching unit 106 to the used signal input terminal. Therefore, the scope unit 3 is determined to be unused by the MPU 102.
When the fuse 108 is cut, a HIGH signal having information that the scope unit 3 has been used is input from the switching unit 106 to the used signal input terminal. Thus, the MPU 102 determines that the scope unit 3 is in a used state.

  The warning unit 112 receives usage status information of each of the first warning and the second warning from the MPU 102.

  When the warning unit 112 receives the first warning from the MPU 102, the warning unit 112 transmits a warning signal to the video processor 82. The warning unit 112 may output a warning such as a sound when the first warning is received. The warning unit 112 may display a warning such as blinking on the monitor 84.

  When the warning unit 112 receives the second warning, the warning unit 112 warns the operator, for example, with a sound that the endoscope image is not displayed on the monitor 84. This sound is different from the sound in the first warning. The warning unit 112 may display a warning such as blinking on the monitor 84. The warning unit 112 transmits an instruction signal for preventing the video processor 82 from displaying an endoscopic image after the warning. As described above, the warning unit 112 outputs the warning signal or the warning signal when the measurement time exceeds the inspectable time or when the MPU 102 determines that the scope unit 3 is in a used state from the state of the fuse 108. Output a warning.

  The measuring unit 114 stores a set time that is set in advance to a desired value. The set time is a time (inspectable time) from when the MPU 102 determines that the scope unit 3 has been used until the monitor output of the endoscopic image is stopped. Within this time, the endoscope system 1 is movable for examination. When the measurement unit 114 receives the above-described instruction (signal) from the MPU 102, the measurement unit 114 starts measuring time and transmits measurement time information to the MPU 102. Further, when the measured time reaches the testable time, the measuring unit 114 transmits an information signal indicating that to the MPU 102.

  When the MPU 102 determines that the scope unit 3 is in a used state from the signal transmitted from the detection unit 104 as described above, the endoscope stopping unit 110 having the warning unit 112 and the measurement unit 114 After the inspectable time has elapsed, the monitor output of the endoscope image is stopped, and the endoscope system 1 is stopped. When the MPU 102 determines that the scope unit 3 is in a used state from the state of the fuse 108, the endoscope stop unit 110 stops the monitor output of the endoscope image and stops the endoscope system 1. .

  The video processor 82 outputs the endoscopic image to the monitor 84.

The video processor 82 also receives a warning signal from the warning unit 112 and causes the monitor 84 to display usage status information (warning signal) such as information indicating that the scope unit 3 has started to be used and remaining time information.
In addition, the video processor 82 receives an instruction signal for not displaying an endoscopic image from the warning unit 112, controls so that the endoscopic image is not displayed on the monitor 84, and the scope unit 3 has been used for the monitor 84. Display a warning.

  The monitor 84 displays one of an endoscopic image, usage status information received from the video processor 82, and a warning that the scope unit 3 has been used. When the video processor 82 receives an instruction signal for not displaying an endoscopic image from the warning unit 112, the monitor 84 does not display the endoscopic image.

  In the above description, the configuration of the MPU 102, the detection unit 104, the switching unit 106, the fuse 108, and the measurement unit 114 when the air / water pump 71 is activated has been described. The same applies when starting (suctioning fluid).

Next, an operation method of the endoscope system will be described with reference to a flowchart shown in FIG.
The scope unit 3 is connected to the light source device 72 via the universal cord 6, the connector 8, and the connector receiver 74. The scope unit 3 is connected to the video processor 82 via the universal cord 6, the connector 8, the electrical connector portion 78, and the electrical cable 80. When the video processor 82 and the light source device 72 are powered on, the MPU 102 controls the entire endoscope system 1. At this time, the changeover switch 106S is connected to the resistor R1, and the changeover unit 106 maintains the reading mode.

  Next, the MPU 102 receives a HIGH or LOW signal from the switching unit 106 at the used signal input terminal in order to determine whether or not the fuse 108 is cut. The MPU 102 determines whether or not the scope unit 3 is unused from this signal (Step 1).

  When receiving the LOW signal, the MPU 102 determines that the fuse 108 is turned on and the scope unit 3 is not used (Step 1: Yes). Next, when the air / water pump 71 is driven and the current value rises to a certain value, the fluid flows into the body cavity. The detection unit 104 measures a current value and transmits a signal having this measurement result to the MPU 102. The MPU 102 receives this signal, compares it with a threshold value, and determines whether or not the scope unit 3 is used (Step 2).

  When the MPU 102 detects that the current value exceeds the threshold value, the MPU 102 determines that the scope unit 3 has been used (Step 2: Yes). At that time, the MPU 102 transmits a control signal to the switching unit 106 to switch the changeover switch 106S to be connected to the resistor R2. Thereby, the switching unit 106 maintains the write mode (Step 3). A power source (not shown) of the switching unit 106 causes a current having a large value to flow through the fuse 108 and cuts the fuse 108.

  Next, the changeover switch 106S is changed over to be connected to the resistor R1, and the changeover unit 106 maintains the reading mode (Step 4). The MPU 102 receives a HIGH signal from the switching unit 106 at the used signal input terminal, and determines that the scope unit 3 has been used.

  The MPU 102 initializes the measurement time in the measurement unit 114 (Step 5), and causes the measurement unit 114 to start measuring time (Step 6). In addition, the MPU 102 transmits usage status information to the warning unit 112 (Step 7).

  When the warning unit 112 receives the usage status information, the warning unit 112 transmits a warning signal to the video processor 82, and the video processor 82 notifies the monitor 84 of usage status information such as that the scope unit 3 has started to be used and the remaining time. Display. The warning unit 112 may output a warning such as a sound. The warning unit 112 may display a warning on the monitor 84 by blinking or the like. Thus, the MPU 102 causes the warning unit 112 to warn that the scope unit 3 has started to be used (first warning) (Step 8).

  Next, the MPU 102 determines whether or not the measurement time measured by the measurement unit 114 exceeds the inspectable time (Step 9). The MPU 102 manages the measurement time by the measurement unit 114, thereby preventing the endoscope system 1 from stopping immediately after the fluid flows. Further, the scope unit 3 treats, for example, tissue in the body cavity within this measurement time, and is removed from the body cavity.

  When the MPU 102 determines that the measurement time exceeds the inspectable time (Step 9: Yes), the MPU 102 restricts the use of the endoscope system 1 (second warning) (Step 10).

  Specifically, the MPU 102 transmits usage status information that instructs the warning unit 112 not to display an endoscope image (end of the endoscope apparatus). The warning unit 112 warns the operator, for example, with a sound, for example, that the endoscope image is not displayed on the monitor 84. This sound is different from the sound in the first warning. The warning unit 112 transmits an instruction signal for preventing the video processor 82 from displaying an endoscopic image after the warning. The video processor 82 controls the monitor 84 so as not to display the endoscopic image. The monitor 84 displays a warning that the scope unit 3 has been used, and does not display an endoscopic image.

  Thus, the MPU 102 prevents the re-insertion after the scope unit 3 treats the tissue in the body cavity and is removed from the body cavity by causing the warning unit 112 to output a warning. Note that the MPU 102 causes the warning unit 112 to stop the first warning at Step 8 at Step 10.

  Next, the MPU 102 determines whether or not the scope unit 3 has been removed from the light source device 72 and the video processor 82 (Step 11). When the MPU 102 determines that the scope unit 3 has been removed from the light source device 72 and the video processor 82 (Step 11: Yes), the MPU 102 initializes the measurement time, and displays the endoscope image that is not displayed again, The warning unit 112 stops the second warning and ends the operation (Step 12).

  In Step 1 described above, when the used scope unit 3 is connected to the light source device 72, the switching unit 106 is switched to the reading mode, and the MPU 102 receives a HIGH signal from the switching unit 106 at the used signal input terminal. Receive. Therefore, the MPU 102 determines that the scope unit 3 is not unused (used) (Step 1: No). In this case, the process proceeds to Step 10 and the MPU 102 restricts the use of the endoscope system 1.

  In Step 11 described above, when the MPU 102 determines that the scope unit 3 is not detached from the light source device 72 and the video processor 82 (Step 11: No), the MPU 102 returns to Step 10.

  In Step 2, when the MPU 102 detects that the current value does not exceed the threshold value, it determines that the scope unit 3 is not used (Step 2: No). Thereby, the MPU 102 considers that the scope unit 3 is not inserted in the body cavity. Therefore, the endoscope system 1 can continue normal operation. At that time, the MPU 102 determines whether or not the scope unit 3 has been removed from the light source device 72 and the video processor 82 (Step 13). When the MPU 102 determines that the scope unit 3 has been removed from the light source device 72 and the video processor 82 (Step 13: Yes), the MPU 102 proceeds to Step 12. When the MPU 102 determines that the scope unit 3 is not detached from the light source device 72 and the video processor 82 (Step 13: No), the MPU 102 returns to Step 1.

  In Step 9, when the MPU 102 does not determine that the measurement time has exceeded the inspectable time (Step 9: No), the MPU 102 regards that the measurement time has not exceeded the inspectable time, and the scope unit 3 is connected to the light source device 72. It is then determined whether or not the video processor 82 has been removed (Step 14). When the MPU 102 determines that the scope unit 3 has been removed from the light source device 72 and the video processor 82 (Step 14: Yes), the process proceeds to Step 12. When the MPU 102 determines that the scope unit 3 is not detached from the light source device 72 and the video processor 82 (Step 14: No), the MPU 102 returns to Step 6.

  In Steps 11, 13, and 14, the MPU 102 connects the scope unit 3 to the light source device 72 and the video processor 82 from the connection state of the fuse 108 and the switching unit 106 and the connection state of the electrical connector unit 78 and the video processor 82, for example. It is determined whether or not there is. In Steps 11, 13, and 14, the MPU 102 determines whether or not the scope unit 3 has been detached from the light source device 72 and the video processor 82. However, in the present embodiment, the present invention is not limited to this. For example, the operation may be ended by an inspection end button (not shown). For example, a signal is output when an examination end button is pressed. The MPU 102 may perform the operation of Step 12 when receiving this signal.

  Next, an operation method for preventing re-insertion of the scope unit 3 inserted into the body cavity by detecting that the fluid has flowed through the suction conduit will be described.

  Since this operation differs only in the operation of Step 2 in FIG. 6, only this portion will be described.

  When the suction pump 70 is driven and the current value rises to a certain value, the fluid is sucked from the body cavity. The detection unit 104 measures a current value and transmits a signal having this measurement result to the MPU 102. The MPU 102 receives this signal, compares it with a threshold value, and determines whether or not the scope unit 3 is used (Step 2).

  Since the subsequent operation is the same as that in the case of supplying or supplying fluid as described above, the description thereof is omitted.

  Thus, in the endoscope system 1 of the present embodiment, when the unused scope unit 3 is connected to the light source device 72 and the suction pump 70 or the air / water supply pump 71 is activated, the detection unit 104 The current value of the suction pump 70 or the air / water pump 71 is detected. When the current value exceeds the threshold value, the MPU 102 detects that the fluid has flowed through the pipeline. Based on the detection result acquired from the detection unit 104, the MPU 102 switches the changeover switch 106S so as to cut the fuse 108, receives a HIGH signal from the switching unit 106, and determines that the scope unit 3 has been used. At that time, the MPU 102 causes the warning unit 112 to warn that the endoscope has started to be used (first warning).

  When the used scope unit 3 is connected to the light source device 72 (Step 1: No) or when the measurement time exceeds the inspectable time (Step 8: Yes), the monitor 84 indicates that the scope unit 3 has been used. A warning (second warning) is displayed and the endoscopic image is not displayed. When the scope unit 3 is detached from the light source device 72 and the video processor 82, the MPU 102 initializes the measurement time, displays the endoscope image that is not displayed again, and issues a second warning to the warning unit 112. Stop and end operation.

  Thereby, the endoscope system 1 of this embodiment can prevent re-insertion after removing the insertion part inserted in the body cavity. That is, the endoscope system 1 according to the present embodiment can prevent a used endoscope from being reused as it is.

  Further, in the endoscope system 1 of this embodiment, after the unused insertion portion 2 is inserted into the body cavity, the usage time is managed by the measurement portion 114, and the insertion portion 2 can be operated for a desired time. is there. Therefore, in the endoscope system 1 of the present embodiment, when the unused insertion portion 2 is inserted into the body cavity and the fluid flows into the body cavity by the air / water feed pump 71, or the fluid from the body cavity by the suction pump 70 It is possible to prevent the unused insertion part 2 from being detected as being used and the operation of the endoscope system 1 from being terminated immediately after the detection.

  In the endoscope system 1 of the present embodiment, the fuse 108 is mounted on the connector 8. For example, when the scope unit 3 has been used, the fuse 108 is cut. Therefore, when the scope unit 3 is connected to the light source device 72, the MPU 102 detects that the scope unit 3 has been used. As described above, when the scope unit 3 is connected to the light source device 72, the endoscope system 1 according to the present embodiment can determine from the state of the fuse 108 that the scope unit 3 has been used, and re-enter the body cavity. Insertion can be prevented.

  Further, this embodiment can be made inexpensive because the fuse 108 is used to detect the insertion state of the insertion portion 2.

  The warning unit 112 outputs a sound, but the present invention is not limited to this. For example, a character, a line, an image, or the like that calls attention may be displayed on the monitor 84.

  The monitor 84 may display at least one of the measurement time and the remaining time.

  In the first embodiment described above, it is detected from the state of the fuse 108 whether or not the insertion portion 2 has been inserted. However, the present invention is not limited to this. For example, as shown in FIG. 7 in the first modification, the scope unit 3 may be provided with a non-volatile memory 120 such as an EEPROM as a use state storage unit. The memory 120 stores used information indicating that the insertion unit 2 has been inserted into the body cavity and has been used.

  For example, when the MPU 102 detects that the current value of the air / water pump 71 exceeds a threshold value, the MPU 102 determines that the air / water pump 71 has flowed fluid. The MPU 102 outputs a control signal having a detection result to the memory 120. The memory 120 stores the use state (usage information) of the pipeline by acquiring this control signal (used signal).

When the scope unit 3 having the used insertion section 2 is connected to the light source device 72, the MPU 102 determines that the insertion section 2 is inserted into the body cavity from the storage state of the memory 120 and has been used.
Thereby, this modification can acquire the same effect as a 1st embodiment.

Next, a second embodiment according to the present invention will be described with reference to FIG.
FIG. 8 is a diagram showing a control configuration of the endoscope system in the present embodiment. The same parts as those in the first embodiment described above are denoted by the same reference numerals, and detailed description thereof is omitted. Unlike the first embodiment described above, the endoscope system 1 in the present embodiment detects the pressing state of the suction button 36 and the air / water supply button 38 so that the insertion portion 2 is inserted into the body cavity. Detect whether or not used.

  As shown in FIGS. 1 to 3, the suction button 36 and the air / water supply button 38 are provided in the operation unit 4. The detection unit 104 detects, for example, whether the air / water supply button 38 is pressed for water supply in the air / water supply button 38. When detecting the pressed state of the air / water supply button 38, the detection unit 104 outputs a detection result to the MPU 102 as in the first embodiment. This detection operation is the same when the suction button 36 is pressed for suction. Since the operation after the suction button 36 or the air / water supply button 38 is pressed and the detection unit 104 outputs the detection result to the MPU 102 is the same as that in the first embodiment, the description thereof is omitted. In addition, the detection unit 104 detects whether or not the air supply / water supply button 38 is blocking the hole 92 for air supply. When detecting that the hole 92 is blocked, the detection unit 104 outputs a detection result to the MPU 102 as in the first embodiment. Since the operation after the detection unit 104 outputs the detection result to the MPU 102 is the same as that in the first embodiment, a description thereof will be omitted.

  As described above, in the present embodiment, whether or not the insertion portion 2 is inserted into the body cavity by using the pressed state of the air / water supply button 38, the state of the hole 92, and the pressed state of the suction button 36 has been used. To detect. Thereby, this embodiment can acquire the same effect as a 1st embodiment mentioned above. In the present embodiment, the insertion portion 2 is inserted into the body cavity from the state of the air / water feed button 38, the hole 92, and the suction button 36 without being affected by the current value of the air / water feed pump 71. Therefore, it is possible to detect that the insertion portion 2 has been used with higher accuracy.

  As described above, when the air / water supply button 38 is individually divided for air supply and water supply, the detection unit 104 may detect the respective pressing states.

  As described above, the detection unit 104 detects the state of the air / water supply button 38, the hole 92, and the pressed state of the suction button 36. However, the present invention is not limited to this. For example, as a first modification, a magnet 122 may be provided in the pressing portion 90 of the air / water supply button 38 as shown in FIG. In the air / water supply button 38, a magnetic detection unit 124 such as a hall sensor is provided at the position farthest from the magnet 122 to output an output signal corresponding to the relative distance to the magnet 122 to the detection unit 104. Yes.

  When the air / water supply button 38 is pressed during water supply, the spring 125 is bent and the relative distance between the magnet 122 and the magnetic detection unit 124 changes as shown in FIG. The magnetic detection unit 124 outputs an output signal corresponding to the relative distance to the detection unit 104.

  The detection unit 104 detects whether or not the air / water supply button 38 is pressed from the output signal. The detection unit 104 outputs the detection result to the MPU 102 as in the first embodiment. This detection operation is the same when the suction button 36 is pressed for suction. Since the operation after the suction button 36 or the air / water supply button 38 is pressed and the detection unit 104 outputs the detection result to the MPU 102 is the same as that in the first embodiment, the description thereof is omitted.

  In the case of air supply, the hole 92 only needs to be closed. Therefore, the air supply / water supply button 38 is not pressed strongly compared to the case of water supply, and the change in relative distance is reduced compared to FIG. Good. Therefore, an output signal corresponding to this distance is output to the detection unit 104. The detection unit 104 detects whether or not the air / water supply button 38 is pressed from the output signal. The detection unit 104 outputs the detection result to the MPU 102 as in the first embodiment. Since the operation after the detection unit 104 outputs the detection result to the MPU 102 is the same as that in the first embodiment, a description thereof will be omitted.

  Thus, this modification can obtain the same effects as those of the first embodiment.

  In addition, in the case of air supply or water supply, the present modification detects whether or not the relative distance is equal to or greater than a threshold value set in the same manner as the current value in the first embodiment, and is air supply or water supply. You may judge.

  The pressing state of the air / water supply button 38 may be divided into two stages. For example, when the air / water supply button 38 is pressed once, the air 61 is supplied. Further, when the air / water feed button 38 is pressed, the liquid 62 is fed. The relative distance between the magnet 122 and the magnetic detection unit 124 when the air / water supply button 38 is pressed once (air supply) is the same as the magnet 122 when the air / water supply button 38 is pressed twice (liquid supply). This is different from the relative distance of the magnetic detection unit 124. Therefore, the output signals output from the magnetic detection unit 124 are different. Therefore, the detection unit 104 can detect whether or not the insertion unit 2 has been inserted into the body cavity.

Next, a third embodiment according to the present invention will be described with reference to FIG.
FIG. 10 is a diagram showing a control configuration of the endoscope system in the present embodiment. The same parts as those in the first embodiment described above are denoted by the same reference numerals, and detailed description thereof is omitted. Unlike the first embodiment described above, the endoscope system 1 according to this embodiment includes pressure detection units 126a and 126b such as pressure sensors. The pressure detector 126a is provided in the air / water supply tube 16a, for example, and detects the pressure in the air / water supply tube 16a. The pressure detector 126b is provided in the suction tube 24, for example, and detects the pressure in the suction tube 24.

  For example, when the air / water feed pump 71 is activated and the liquid 62 is fed into the body cavity, the pressure detector 126a detects the pressure in the air / water feed tube 16a. The pressure detection unit 126a detects whether or not the detected pressure value exceeds a threshold value (desired value) set in advance by a setting unit (not shown). When detecting that the pressure value exceeds the threshold value, the pressure detection unit 126a outputs the detection result to the MPU 102. Since the operation after outputting the detection result to the MPU 102 is the same as that in the first embodiment, a description thereof will be omitted. The same applies to air supply and suction.

  As described above, in the present embodiment, the pressure detectors 126a and 126b detect the pressure in the air / water feeding tube 16a and the suction tube 24, so that the insertion portion 2 is inserted into the body cavity as in the first embodiment. It can be detected whether it has been used. Thereby, the effect similar to 1st Embodiment can be acquired.

  In the present embodiment, the pressure in the air / water supply tube 16a is measured, but it is not necessary to be limited to this. For example, in order to detect the pressure in each of the water supply pipe and the air supply pipe, the pressure detection unit 126a includes, for example, an air supply pipe such as the air supply tube 20 and a water supply pipe such as the water supply tube 22. It may be provided on the road.

  In the case of water supply, the pressure detector 126a may detect the pressure in the water supply tank 52. Moreover, you may provide the detection part which detects the liquid level height in the water supply tank 52. FIG.

  In the present embodiment, the pressures in the air / water supply tube 16a and the suction tube 24 are measured. However, the present invention is not limited to this. For example, as shown in FIG. Flow rate detectors 128a and 128b such as a flow rate sensor for detecting the flow rate) may be provided in the air / water supply tube 16a and the suction tube 24.

FIG. 1 is a schematic configuration diagram of an endoscope system according to the first embodiment of the present invention. FIG. 2 is a schematic configuration diagram showing an arrangement state of each pipe line arranged in the endoscope system. FIG. 3 is a schematic view showing an air supply conduit. FIG. 4 is a diagram illustrating a control configuration of the endoscope system. FIG. 5 is a diagram showing current values when the pump is started. FIG. 6 is a flowchart illustrating an operation method according to the first embodiment. FIG. 7 is a diagram showing a modification of the control configuration using a memory instead of a fuse. FIG. 8 is a diagram illustrating a control configuration of the endoscope system according to the second embodiment. FIG. 9 shows a magnet, an air / water feed button having a magnetic detection unit, and a suction button. FIG. 10 is a diagram illustrating a control configuration of the endoscope system according to the third embodiment. FIG. 11 is a diagram illustrating a modification of the control configuration using the flow rate detection unit instead of the pressure detection unit in the third embodiment.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Endoscope system, 2 ... Insertion part, 3 ... Scope unit, 4 ... Operation part, 6 ... Universal cord, 8 ... Connector, 16 ... Air supply / water supply nozzle, 16a ... Air supply / water supply tube, 18 ... Tip Opening part, 20 ... Air supply tube, 22 ... Water supply tube, 24 ... Suction tube, 36 ... Suction button, 38 ... Air supply / water supply button, 44 ... Treatment instrument insertion channel, 52 ... Water supply tank, 56 ... Air supply tube, 70 DESCRIPTION OF SYMBOLS ... Suction pump, 71 ... Air supply / water supply pump, 72 ... Light source device, 82 ... Video processor, 84 ... Monitor, 90 ... Press part, 102 ... MPU, 104 ... Detection part, 106S ... Switch, 106 ... Switching part, 108 ... fuse, 110 ... endoscope stop means, 112 ... warning part, 114 ... measurement part, 126a, 126b ... pressure detection part, 128a, 128b ... flow rate detection part.

Claims (7)

A detection unit for detecting a state in which a fluid has flowed through a conduit disposed inside the endoscope;
A use state storage unit provided in the endoscope, the storage state of which changes depending on whether or not the endoscope is used;
Control that is connected to the detection unit and the use state storage unit, determines whether or not the endoscope is used based on a detection result output from the detection unit, and changes the storage state of the use state storage unit And
Equipped with,
When the control unit determines that the endoscope is in use based on the detection result output from the detection unit, the control unit stops the endoscope after a predetermined set time has elapsed. or an endoscope system characterized by chromatic endoscopic stopping means for the endoscope is stopped when the endoscope from the state of the use state storage unit is determined to be the state of there use . The endoscope stopping means, when the control unit determines that the endoscope is in use based on the detection result output from the detection unit, a measurement unit that starts measuring time,
At least when the time measured by the measurement unit has passed the set time, or when the control unit determines that the endoscope is in use from the state of the use state storage unit, A warning part that outputs a warning in either case,
The endoscope system according to claim 1, further comprising:   The conduit includes an air supply conduit for supplying a gas into the body cavity, a water supply conduit for supplying a liquid into the body cavity, and a suction for sucking the fluid from the body cavity. The endoscope system according to claim 1, further comprising a pipeline. An air / water supply section for supplying the gas into the body cavity via the air supply conduit, or for supplying the liquid into the body cavity via the water supply conduit;
A suction section for sucking the fluid from the body cavity via the suction conduit;
Have
The detection unit detects the current value of the air / water supply unit driven to supply the gas or supply the liquid, and the current of the suction unit when driven to suck the fluid The endoscope system according to claim 3, wherein a value is detected. An air / water supply section for supplying the gas into the body cavity via the air supply conduit, or for supplying the liquid into the body cavity via the water supply conduit;
A suction section for sucking the fluid from the body cavity via the suction conduit;
An air / water supply starting unit for starting the air / water supply unit;
A suction activation part for activating the suction part;
Have
The endoscope system according to claim 3, wherein the detection unit detects a pressing state of the air / water supply starting unit and the suction starting unit.   The inner part of Claim 3 characterized by the above-mentioned. The said detection part is a pressure detection part which detects the pressure in the said pipeline for air supply, the said pipeline for water supply, and the said pipeline for suction. Endoscopic system.   The inner part of Claim 3 characterized by the above-mentioned. The said detection part is a flow volume detection part which detects the flow volume in the said pipeline for air supply, the said pipeline for water supply, and the said pipeline for suction. Endoscopic system.

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