JP4364051B2 - Endoscope - Google Patents

Description

  The present invention relates to an endoscope that is inserted into a body cavity or the like and performs an endoscopic examination or the like.

In recent years, endoscopes provided with illumination means and observation means at the distal end of an elongated insertion portion have been widely adopted in the medical field and the industrial field.
In particular, in the case of an endoscope having a flexible insertion portion, a bending portion is provided near the distal end of the insertion portion so that it can be inserted into a bent body or the like, and a desired direction can be observed. A bending operation means is provided so that the bending portion can be operated to bend (angle operation).
By bending the bending portion in this way, the insertion portion can be easily inserted into a bent body cavity.

In order to further improve the insertability, it is convenient to be able to detect the state in which the bending portion is pressed against the inner wall or the like. In this case, an electric pressure sensor may be provided in the curved portion, but since an illuminating means is necessarily required in an endoscope, a very useful usage method is possible if a part of the illumination light can be used. It becomes.
JP 7-124104 A

In the electronic endoscope disclosed in Japanese Patent Laid-Open No. 7-124104, a pressure sensitive sensor formed of a strain gauge is provided in the bending portion to detect pressure, and the bending operation means uses the output of the pressure sensitive sensor. The bending operation is restricted.
The conventional example of the above publication performs pressure detection electrically, and does not allow the above-described illumination light to be used efficiently.

(Object of invention)
The present invention has been made in view of the above points, and provides an endoscope that can be used for improving insertability by using a part of illumination light from an illumination unit for pressure detection or pressure sensing. With the goal.

The present invention provides an endoscope in which a distal end portion provided with an illumination window and an observation window and a bendable bending portion are provided in an insertion portion.
First light guiding means for guiding a part of the illumination light to be emitted from the illumination window to the peripheral portion including the curved portion;
A pressure deforming member disposed at least in the peripheral portion including the curved portion, the light guided by the first light guide means being emitted to the inside, and the shape changing according to the amount of pressure from the outside; ,
A second light guide means for receiving and guiding the light emitted into the pressing deformation member;
Light detection means for detecting light guided by the second light guide means;
It is characterized by comprising.
With the above configuration, the amount of pressure applied to the inner wall of the body cavity in the case where the bending portion or the like is bent using a part of the illumination light can be used to improve the insertability.

  According to the present invention, since the amount of pressure exerted on the inner wall of the body cavity is detected when a curved portion or the like is bent using a part of the illumination light, the detection information is improved in insertability, etc. Available to:

  Embodiments of the present invention will be described below with reference to the drawings.

FIGS. 1 to 21 relate to a first embodiment of the present invention, FIG. 1 shows an overall configuration of an endoscope system equipped with the present invention, FIG. 2 shows a data communication mode, and FIG. 3 shows an endoscope of the present invention. 4 shows the general configuration of the mirror, FIG. 4 shows the overall configuration of the endoscope system provided with the present embodiment, FIG. 5 shows a specific external shape of the periphery of the AWS unit, and FIG. 6 shows the attachment / detachment to the AWS unit. FIG. 7 shows the structure of the AWS adapter, showing a state where the flexible AWS adapter is attached and removed.
FIG. 8 shows the internal configuration of the endoscope system control device and the AWS unit, FIG. 9 shows the detailed configuration of the endoscope of the first embodiment, and FIG. 10 shows the internal configuration of the distal end side of the insertion portion. 11 shows the configuration of the optical pressure detection means, FIG. 12 shows the schematic characteristics of the conductive polymer artificial muscle (EPAM) used for the angle member and the hardness variable member, and FIG. 13 shows C of FIG. FIG. 14 shows a configuration of a contactless transmission unit in which the base end of the tube unit is detachably connected to the operation unit main body without a contact.

15 shows the configuration of the electrical system in the components provided in the endoscope, FIG. 16 shows the configuration of the electrical system of the main part of the endoscope system control device, and FIG. 17 shows the configuration of the electrical system of the AWS unit. FIG. 18 shows a typical display example of the monitor display surface of the observation monitor and a specific example of the menu display, FIG. 19 shows the operation content of the activation processing of the AWS unit, and FIG. 20 shows the activation of the endoscope. FIG. 21 shows a control process for the angle operation.
Before describing the specific configuration of the present invention, the schematic configuration of the present invention will be described with reference to FIGS.
As shown in FIG. 1, an endoscope system 1 having the present invention is a flexible endoscope (also referred to as a scope) 3 that is inserted into a body cavity of a patient (not shown) lying on an examination bed 2 and performs an endoscopic examination. The endoscope 3 is connected to an air supply / water supply / suction unit (hereinafter abbreviated as AWS unit) 4 having an air supply, water supply, and suction function, and an imaging device built in the endoscope 3. An endoscope system control device 5 that performs signal processing and control processing for various operation means provided in the endoscope 3, a liquid crystal monitor that displays a video signal generated by the endoscope system control device 5, and the like And an observation monitor 6.

In addition, the endoscope system 1 is connected to an image recording unit 7 for filing, for example, a digital video signal generated by the endoscope system control device 5 and the AWS unit 4, and is inserted into an insertion portion of the endoscope 3. When a shape detection coil (hereinafter abbreviated as UPD coil) is incorporated, the position of each UPD coil is detected by receiving an electromagnetic field signal generated by the UPD coil, etc. And a UPD coil unit 8 for displaying the shape of the insertion portion.
The image recording unit 7 is connected to a LAN 9 in the hospital where the endoscope system 1 is provided, and the image recording unit 7 is filed in the image recording unit 7 by each terminal device connected to the LAN 9 by wire or wirelessly. The image etc. can be referred.

Further, as shown in FIG. 1, the AWS unit 4 and the endoscope system control device 5 transmit and receive information (data) wirelessly. In FIG. 1, the endoscope 3 is connected to the AWS unit 4 via a cable, but information (data) may be transmitted and received (bidirectional transmission) wirelessly. Further, the endoscope system control device 5 may transmit and receive information to and from the endoscope 3 wirelessly.
2A to 2C show three methods in a transmission / reception unit (communication unit) that performs data transmission / reception between units and devices in the endoscope system 1 or between the endoscope 3 and the unit or device. Show. 2A, as a specific example, the case of the AWS unit 4 and the endoscope system control device 5 will be described.

FIG. 2A shows a wireless system, in which the data communication control unit 11 built in the AWS unit 4 modulates the data via the data transmission unit 12 and transmits it wirelessly from the antenna unit 13 to the endoscope system control device 5.
In addition, the AWS unit 4 receives data wirelessly transmitted from the endoscope system control device 5 side by the antenna unit 13, demodulates the data by the data reception unit 14, and transmits the data to the data communication control unit 11. In the present invention, when data is transmitted by a wireless system, a wireless LAN having a maximum data communication speed of 54 Mbps is formed according to, for example, the IEEE 802.11g standard.
FIG. 2B illustrates a wired system. As a specific example, a case where data transmission / reception is performed between the endoscope 3 and the AWS unit 4 will be described. The data communication control unit 11 built in the endoscope 3 transmits the data from the electrical connector 15 to the AWS unit 4 via the data transmission unit 12 ′. Further, the data transmitted from the AWS unit 4 is sent to the data communication control unit 11 via the electrical connector 15 and the data receiving unit 14 '.

FIG. 2C shows an optical communication method, and a case where data transmission / reception is performed between the AWS unit 4 and the endoscope system control device 5 will be described as a specific example. The data communication control unit 11 built in the AWS unit 4 is connected to an optical communication coupler 16 provided in the AWS unit 4 via a data transmission unit 12 ″ for transmitting and receiving for optical communication and a data reception unit 14 ″. Data is transmitted and received through an optical communication coupler on the endoscope system control device 5 side.
FIG. 3 shows a schematic configuration of the endoscope 3 of the present invention. The endoscope 3 includes an endoscope body 18 and a tube unit 19 that is detachably connected to the endoscope body 18 and is, for example, a disposable type (disposable type). The tube unit 19 has a diameter smaller than that of a conventional universal cable, and in the present embodiment, the tube unit 19 includes only two conduit tubes, a power supply line, and a signal line.
The endoscope main body 18 includes a flexible insertion portion 21 that is inserted into a body cavity, and an operation portion 22 provided at the rear end of the insertion portion 21, and the operation portion 22 includes a base of the tube unit 19. The end is detachably connected.

In addition, an imaging unit using a CCD 25 whose gain is variable inside the imaging device is disposed at the distal end portion 24 of the insertion portion 21 as an imaging device. Further, the distal end portion 24 is provided with a contact sensor 142 (specifically, Example 2 described later) that detects a state in which the distal end portion 24 is in contact (pressure contact) with an inner wall or the like in the body cavity.
In addition, a bending portion 27 that can be bent with a low force is provided at the rear end of the distal end portion 24, and the bending portion 27 is bent by operating the angle / remote control operator 28 provided on the operation portion 22. be able to. This angle / remote control operator 28 is used for angle operation (bending operation), air supply / water supply, suction, etc., remote control operation for the endoscope system control device 5 etc. (specifically, freeze instruction operation, release instruction) Remote control operation as an operation) can be performed. Further, the insertion portion 21 is formed with a portion whose hardness is variable so that the insertion can be performed more smoothly.
Note that a cleaning level detection unit 29 may be provided in the insertion unit 21 so that the cleaning level of the pipeline can be detected.
Next, a more specific configuration of the endoscope system 1 will be described with reference to FIG.

An observation monitor 6 composed of a liquid crystal monitor or the like is disposed adjacent to the side surface of the inspection bed 2, and is displayed on the cart 31 movably disposed near one end portion in the longitudinal direction of the inspection bed 2. Mirror system control device 5, AWS unit 4, image file / LAN / electric knife / ultrasonic unit (image file unit, wireless LAN or wired LAN, electric knife device, ultrasonic unit, etc. are simplified) 32 are arranged. A monitor 33 with a touch panel is arranged at the top.
Further, the UPD coil unit 8 is embedded in the upper surface portion of the examination bed 2 on which the patient lies. The UPD coil unit 8 is connected to the AWS unit 4 by a UPD cable 34.

  In the present embodiment, the AWS unit 4 and the endoscope system control device 5 perform data transmission / reception by wireless transmission / reception units 77 and 101 as shown in FIG. 8, for example. As shown in FIG. 4, the observation monitor 6 is connected to a monitor connector of the endoscope system control device 5 by a monitor cable 35.

In addition, as shown in FIG. 4, the transmission / reception units 101 and 36 are attached to the endoscope system control device 5 and the observation monitor 6, respectively, and a video signal is transmitted from the endoscope system control device 5 to the observation monitor 6, Endoscopic images corresponding to the video signals may be displayed on the display surface.
As will be described later, the endoscope system control device 5 includes an image of the insertion portion shape (UPD image) of the endoscope 3 detected using the UPD coil unit 8 together with image data captured by the CCD 25 from the AWS unit 4 side. Therefore, the endoscope system control device 5 sends video signals corresponding to these image data to the observation monitor 6 so that the UPD image can be displayed together with the endoscope image on the display surface. ing.

The observation monitor 6 is composed of a high-resolution TV (HDTV) monitor so that a plurality of types of images can be simultaneously displayed on the display surface.
In this embodiment, a storage recess is formed at one end in the longitudinal direction of the inspection bed 2 and a position below the end, and the tray transporting trolley 38 is slidable in the storage recess. It can be stored in. A scope tray 39 in which the endoscope 3 shown in FIG. 9 is housed is placed on the tray transporting trolley 38.
The scope tray 39 storing the sterilized or sterilized endoscope 3 can be transported by the tray transporting trolley 38 and can be stored in the storing recess of the inspection bed 2. The operator can pull out the endoscope 3 from the scope tray 39 and use it for the endoscopy, and can store it again in the scope tray 39 after the end of the endoscopy. Thereafter, the scope tray 39 in which the used endoscope 3 is accommodated is transported by the tray transporting trolley 38, whereby sterilization or disinfection can be performed smoothly.

As shown in FIG. 4, for example, the AWS unit 4 is provided with a scope connector 40. Then, a scope connector 41 (of the endoscope 3) is detachably connected to the scope connector 40 as shown in FIG.
In this case, a more specific external shape of the scope connector 40 on the AWS unit 4 side is shown in FIGS. 7 shows the structure of an AWS adapter 42 that is detachably attached to the scope connector 40 of the AWS unit 4. FIG. 8 shows the inside of the scope connector 40 on the AWS unit 4 side and the scope connector 41 on the endoscope 3 side. The structure is shown in a connected state.
Actually, as shown in FIG. 6B, a concave-shaped AWS adapter mounting portion 40a is provided on the front surface of the AWS unit 4, and the AWS adapter mounting portion 40a includes an AWS adapter (pipe) shown in FIG. A scope connector 40 is formed by attaching a (road connection adapter) 42, and the scope connector 41 of the endoscope 3 is connected to the scope connector 40.

The AWS adapter mounting portion 40a is provided with an electrical connector 43 for connecting the scope, an air supply connector 44, and a pinch valve 45. The inner end face of the AWS adapter 42 is detachably mounted on the AWS adapter mounting portion 40a. The scope connector 41 of the endoscope 3 is connected from the outer end face side.
Details of the AWS adapter 42 are shown in FIG. 7A is a front view of the AWS adapter 42, FIGS. 7B and 7C are left and right side views, and FIGS. 7D and 7E are views of FIG. 7A. AA 'and BB' sectional views are shown respectively.
In the AWS adapter 42, a scope connector 41 is inserted into a recess 42a on the front surface. In this case, an electrical connector portion of the scope connector 41 is inserted into a through hole 42b provided in the recess, and the through hole 42b is inserted into the through hole 42b. It is connected to an electrical connector 43 for connecting a scope provided on the facing AWS unit 4.

Further, an air / water supply connector 42c and a suction connector 42d are provided below the through hole 42b, and an air / water supply base 63 and a suction base 64 (see FIGS. 8 and 9) in the scope connector 41 are connected to each other. Is done.
Note that a recess 42f for housing the pinch valve 45 protruding from the AWS adapter mounting portion 40a is provided on the base end surface side of the AWS adapter 42.
As shown in FIG. 7E, the air / water supply connector 42c provided in the AWS adapter 42 has an internal air passage 42e connected to the air supply connector 44 of the AWS unit 4 branched from the internal pipe line communicating therewith. And a water supply cap 46 protruding sideways. Further, the suction connector 42d is a suction base 47 whose side communicating with the side is bent to the side and protrudes to the side surface, and becomes a relief pipe 47a that branches, for example, upward on the way, and the relief pipe 47a is After passing through the inside of the pinch valve 45 on the way, its upper end is open.

The relief pipe 47a is normally set in a released state by the pinch valve 45 when a suction pump (not shown) that forms the suction means is set to a constantly operating state, and the pinch valve when a suction operation is performed. 45 is driven. Then, the relief valve 47a is closed by the pinch valve 45, so that the release is stopped and the suction operation is performed.
As shown in FIG. 5 and the like, the water supply base 46 and the suction base 47 are respectively connected to a water supply tank 48 and a suction device (a suction tank 49b is inserted halfway through a suction tube 49a). . The water tank 48 is connected to the water tank connector 50 of the AWS unit 4. Note that an operation panel 4 a is provided on the upper side of the scope connector 40 on the front surface of the AWS unit 4.

Next, a specific configuration of the endoscope 3 according to the first embodiment of the present invention will be described with reference to FIG.
As described in FIG. 3, the endoscope 3 according to the present embodiment includes an endoscope main body 18 having a flexible insertion portion 21 and an operation portion 22 provided at the rear end thereof, and the endoscope. A disposable type (abbreviated as disposable type) in which a general connector portion 52 at the base end is detachably connected to a connector portion 51 (for tube unit connection) provided near the base end (front end) of the operation portion 22 in the main body 18. Tube unit 19.
At the end of the tube unit 19 is provided the above-mentioned scope connector 41 that is detachably connected to the AWS unit 4.
The insertion portion 21 includes a hard distal end portion 24 provided at the distal end of the insertion portion 21, a bendable bending portion 27 provided at the rear end of the distal end portion 24, and an operation unit from the rear end of the bending portion 27. It consists of up to 22 elongated flexible portions (conduit portion) 53.

A variable hardness called a conductive polymer artificial muscle (abbreviated as EPAM) that can expand and contract by applying a voltage and change its hardness at a plurality of locations in the middle of the soft portion 53, specifically, two locations. Actuators 54A and 54B are provided.
As shown in an enlarged view in FIG. 10, for example, a light-emitting diode (LED) 56 is attached to the inside of the illumination window provided at the distal end portion 24 of the insertion portion 21 as illumination means. The light is emitted forward through a lens integrally attached to the LED 56.
In front of this lens, a transparent optical element 161 is disposed, and illumination light is emitted forward through the optical element 161 and the illumination lens 162 disposed in front of the optical element 161 to illuminate a subject such as an affected part.
In this embodiment, a light branching portion 163 is formed around the optical element 161. FIG. 11A shows a schematic view of the optical element 161 as viewed from the LED 56 side. That is, the optical branching portion 163 is formed by providing a prism or beam splitter having a function of branching into transmitted light and reflected light around the optical element 161.

Then, one end of optical fibers 164a, 164b, 164c, 164d as light guide members is arranged on the side surface that becomes the path of reflected light by the light branching portion 163, and the other ends of the optical fibers 164a, 164b, 164c, 164d are For example, it is fixed inside pressing deformation members 165a, 165b, 165c, 165d provided at the upper and lower corners and the left and right corners of the distal end portion 24 (all are not shown in the drawing).
The pressing deformation member 165i (i = a to d) is, for example, a substantially spherical shape, and is formed of urethane or the like having an appropriate reflection characteristic while being deformed according to the pressing amount.
Further, in the pressing deformation member 165i (i = a to d), one end of the optical fiber 166i paired with the optical fiber 164i is fixed, and the other end of the optical fiber 166i is optically detected. The photodetecting element array 167 is arranged at a position facing the photodetecting element elements constituting the photodetecting element array 167 (note that only the photodetecting element array 167 is shown in the drawing).

  When the pressing deformation member 165i is pressed and deformed, the reflection characteristic of the light guided by the optical fiber 164i in the pressing deformation member 165i changes, and the amount of light incident on the optical fiber 166i changes. Accordingly, when the pressing deformation member 165i is pressed and deformed, the intensity (signal level) of the electric signal detected by the light detection element of the light detection element array 167 via the optical fiber 166i also changes. Note that the photodetecting element array 167 is connected to the control circuit 57 via a signal line.

Then, the control circuit 57 determines that a pressing force of a predetermined value or more has been applied based on whether or not the output change amount has changed by more than a reference value based on the output of the light detection element array 167. When the bending portion 27 is driven to bend, if it is determined that the amount of change in output has changed by a reference value or more, a restricting means for restricting the bending drive is formed. This operation will be described in the angle control of FIG.
In FIG. 11A, the light branching portion 163 is formed to be elongated at the lower side of the optical element 161. However, as shown in FIG. 11B, the light branching portion 163a is formed at the four corners of the optical element 161. 163b, 163c, and 163d may be formed. If it does in this way, it will be easy to light-guide to the press deformation member 165i arrange | positioned in the vertical and horizontal positions in the curved part 27. FIG.

In the case of the configuration shown in FIG. 11B, only a part of the peripheral side of the illumination light is used, so that the pressing amount is detected with almost no decrease in the illumination light that illuminates the subject side. be able to.
In this way, a pressure detecting means for optically detecting the amount of pressure acting on the upper and lower and left and right corners of the tip 24 using a part of the illumination light (in FIG. 15, simplified contact) Sensor 142 is used).
The LED 56 may be an LED that generates white light, or an R LED, a G LED, and a B LED that generate light in each wavelength region of red (R), green (G), and blue (B). You may comprise using. The light-emitting element that forms the illumination means is not limited to the LED 56, and can also be formed using an LD (laser diode) or the like.

In addition, an objective lens 169 is attached to an observation window provided adjacent to the illumination window, and a CCD 25 having a variable gain function is disposed at the imaging position thereof, thereby forming an imaging means for imaging a subject. Has been. The CCD 25 in this embodiment has a variable gain function built into the CCD element itself, and the gain variable function can easily change the gain of the CCD output signal to several hundred times, so even under illumination light from the LED 56, A bright image with little decrease in S / N is obtained. Further, since the LED 56 has better light emission efficiency than the case of the lamp, the temperature increase in the vicinity of the LED 56 can be suppressed.
One end of each of the LED 56 and the CCD 25 is connected, and the other end of the signal line inserted into the insertion unit 21 is connected to a control circuit 57 that is provided, for example, inside the operation unit 22 and performs centralized control processing (aggregate control processing). ing.
A plurality of UPD coils 58 are arranged at predetermined intervals along the longitudinal direction in the insertion portion 21, and signal lines connected to the respective UPD coils 58 are connected to the UPD coil drive unit 59 provided in the operation portion 22. To the control circuit 57.

In addition, angle actuators 27a formed by arranging EPAM in the longitudinal direction are arranged at four locations in the circumferential direction inside the outer skin of the curved portion 27. The angle actuator 27a and the hardness varying actuators 54A and 54B are also connected to the control circuit 57 via signal lines.
The EPAM used for the angle actuator 27a and the hardness varying actuators 54A and 54B is shown in FIG. 12B by attaching electrodes to both sides of a plate shape and applying a voltage as shown in FIG. As shown, it can shrink in the thickness direction and extend in the longitudinal direction. In addition, as shown in FIG. 12C, this EPAM can vary the amount of distortion in proportion to, for example, approximately the square of the electric field strength E due to the applied voltage.
When used as the angle actuator 27a, the bending portion 27 can be bent in the same manner as a normal wire function by forming a wire shape or the like and extending one and contracting the other side. Further, the hardness can be varied by the expansion or contraction, and the hardness varying actuators 54A, 54B can vary the hardness of the portion by utilizing the function.

In addition, an air / water supply conduit 60 a and a suction conduit 61 a are inserted into the insertion portion 21, and a rear end thereof is a conduit connector portion 51 a opened in the connector portion 51. The tube connector 52a in the general connector portion 52 at the proximal end of the tube unit 19 is detachably connected to the pipe connector portion 51a.
The air / water supply conduit 60 a is connected to the air / water supply conduit 60 b inserted into the tube unit 19, and the suction conduit 61 a is connected to the suction conduit 61 b inserted into the tube unit 19. At the same time, it branches off in the tube connector 52a, opens to the outside, and communicates with a treatment instrument insertion port (abbreviated as forceps port) 62 through which a treatment instrument such as forceps can be inserted. The forceps port 62 is closed by a forceps plug 62a when not in use.
The proximal ends of the air / water supply conduit 60b and the suction conduit 61b serve as an air / water supply base 63 and a suction base 64 in the scope connector 41.

  The air / water supply base 63 and the suction base 64 are connected to the air / water supply connector 42c and the suction connector 42d of the AWS adapter 42 shown in FIGS. As shown in FIG. 7, the air / water supply connector 42 c branches into an air supply line and a water supply line inside the AWS adapter 42. As shown in FIG. 8, the air supply line is connected to an air / water supply pump 65 inside the AWS unit 4 via an electromagnetic valve B <b> 1, and the water supply line is connected to a water supply tank 48. The water supply tank 48 is also connected to the air / water supply pump 65 via the electromagnetic valve B2 on the way. The air / water pump 65 and the electromagnetic valves B1 and B2 are connected to the AWS control unit 66 by a control line (drive line), and opening / closing is controlled by the AWS control unit 66 so that air and water can be supplied. I have to. The AWS control unit 66 also performs suction operation control by controlling opening and closing of the pinch valve 45.

As shown in FIG. 9, the operation unit 22 of the endoscope body 18 is provided with a gripping portion 68 that is gripped by an operator, and a remote control such as a release or a freeze is provided around the gripping portion 68. For example, three scope switches SW 1, SW 2, SW 3 that perform an operation (abbreviated as remote control operation) are provided along the longitudinal axis of the operation unit 22 and are connected to the control circuit 57.
Furthermore, the slope portion Sa formed as an upper surface opposite to the position where the scope switches SW1, SW2, and SW3 are provided in the operation portion 22 is positioned so that it can be operated by the hand holding the grip portion 68. There is provided a waterproof trackball 69 for performing angle operation (curving operation), switching and setting of other remote control operations.
Moreover, FIG. 13 shows a view C in FIG. As shown in FIG. 13, two scope switches SW4 and SW5 are provided on both sides of the trackball 69 on the slope portion Sa at positions that are symmetrical in the left-right direction on both sides in the longitudinal direction of the operation unit 22. . The scope switches SW4 and SW5 are normally assigned the functions of an air / water supply switch and a suction switch.

When the operation unit 22 of the endoscope 3 is viewed from the front in the direction of arrow C in FIG. 8, the trackball 69 is on the center line in the longitudinal direction with respect to the longitudinal direction of the operation unit 22 or the insertion unit 21. The two scope switches SW4 and SW5 are arranged symmetrically and the scope switches SW1, SW2 and SW3 are arranged on the back side along the center line.
As described above, the operation unit 22 is provided with various operation means such as the track ball 69 symmetrically with respect to the central axis in the longitudinal direction, so that the operator holds the grip unit 68 of the operation unit 22. In the case of operation, it is ensured that good operability can be ensured in the same manner in both cases of gripping with the left hand and gripping with the right hand.
The trackball 69 and scope switches SW4 and SW5 are also connected to the control circuit 57. The trackball 69 and the scope switches SW1 to SW5 correspond to the angle / remote control operator 28 in FIG.

Further, the power supply line 71a and the signal line 71b extended from the control circuit 57 are inserted through the tube unit 19 via contactless transmission parts 72a and 72b formed in the connector part 51 and the general connector part 52. The power supply line 73a and the signal line 73b are electrically connected without contact (refer to FIG. 14 for details). The power supply line 73a and the signal line 73b are connected to an electrical connector 74 having a power supply & signal contact in the scope connector 41. In addition, the connector part 51 side in the contactless transmission parts 72a and 72b is called, for example, the contactless transmission unit 51b.
Then, the user connects the scope connector 41 to the AWS unit 4 so that the power line 73a is connected to the power unit 75 via the electrical connector 43 of the AWS unit 4 as shown in FIG. Are connected to the UPD unit 76, the transceiver unit 77, and the AWS control unit 66 (via the power supply unit 75). The transmission / reception unit 77 is connected to an antenna that transmits and receives radio waves by radio.

FIG. 14 shows the configuration of the contactless connection part by the contactless transmission parts 72a and 72b in the connector parts 51 and 52.
The AC power supplied from the power supply unit 75 through the power line 73a inserted through the tube unit 19 is housed in the exterior case of the general connector section 52, and forms the contactless transmission section 72a on the primary coil C1a. To be supplied.
A secondary-side coil C1b is disposed inside the outer case of the connector portion 51, and the primary-side coil C1a and the secondary-side coil C1b are close to each other and electromagnetically coupled in a state where there is little magnetic flux leakage. T1 is formed.
And by this electromagnetic coupling, the alternating current power supplied to this coil C1a is efficiently transmitted to the secondary side coil C1b. The coil C1b is connected to a power supply circuit 78 in the control circuit 57, and the power supply circuit 78 generates DC power required on the control circuit 57 side.

The power supply circuit 78 converts the DC voltage rectified through the rectifying diode D and the smoothing capacitor into a DC voltage necessary for the operation of the control circuit 57 by, for example, the three-terminal power supply IC 79 and the smoothing capacitor. , Supplied to the control circuit 57.
The signal line 71b connected to the control circuit 57 (forming a common signal transmission means) is connected to the coil C2a forming the contactless transmission part 72b, and the coil C2b facing and close to the coil C2a is The signal line 73b inserted through the tube unit 19 is connected. That is, the contactless transmission unit 72b is formed by the transformer T2 that is electromagnetically coupled by the coils C2a and C2b in substantially the same manner as the transformer T1.
A signal is transmitted from the signal line 71b side to the signal line 73b side through the electromagnetically coupled coils C2a and C2b, and also in the reverse direction.

In this embodiment, as explained in FIG. 15, the control circuit 57 centrally controls or manages various operation means, image pickup means, etc., so that the tube unit 19 is inserted. The number of electric signal lines to be reduced can be reduced. Further, even when the function provided in the endoscope 3 is changed, the signal line 73b in the tube unit 19 can be used without change. That is, the signal line 73b forms common signal transmission means for transmitting various signals in common.
As shown in FIG. 14, for example, adjacent to the transformer T2, the magnetic poles different from the magnets M1 and M2 are arranged to face each other, and when connecting the general connector part 52 to the connector part 51, the coil C1a And C1b, and coils C2a and C2b are detachably attached in a state where they are close to each other and face each other. In addition, you may make it provide the uneven | corrugated | grooved part which mutually fits and positions the both connector parts 51 and 52 instead of the magnets M1 and M2.
Thus, the endoscope 3 according to the present embodiment is characterized in that the endoscope body 18 is configured to be detachably connected to the tube unit 19 without contact.
FIG. 15 shows the configuration of the electrical system in the control circuit 57 and the like arranged in the operation unit 22 of the endoscope body 18 and main components arranged in each part of the insertion unit 21.
A CCD 25 and an LED 56 are arranged at the distal end portion 24 of the insertion portion 21 shown at the lower left portion in FIG. 15, and an angle actuator (specifically, in this embodiment) is placed on the bending portion 27 described above in the drawing. EPAM) 27a and an encoder 27c are arranged.

In addition, the soft portion 53 includes a hardness varying actuator 54 and an encoder 54c (specifically, in this embodiment, the hardness varying actuators 54A and 54B are EPAM, but are simply shown as one representative). Are arranged respectively. Further, a UPD coil 58 is disposed in the soft part 53.
In addition, a trackball 69, an air / water supply SW (SW4), a suction SW (SW5), and a scope SW (SW1 to SW3) are arranged on the surface of the operation unit 22 described on the flexible part 53 of the insertion unit 21. Is done. As will be described later, the trackball 69 is used for angle setting, selection and setting of other functions, and the like.
These components shown on the left side of FIG. 15 are connected to a control circuit 57 (in the operation unit 22 in the UPD coil driving unit 59) provided in the operation unit 22 shown on the right side via a signal line. Performs drive control of these functions, signal processing, and the like.

The control circuit 57 includes a state management unit 81 configured by a CPU or the like that manages the control state, and the state management unit 81 is connected to a state holding memory 82 that holds (stores) the state of each unit. The state holding memory 82 has a program holding memory 82a as a control information storage means, and the components shown in FIG. 15 are changed by rewriting the program data as control information stored in the program holding memory 82a. Even in this case, the state management unit 81 (a CPU constituting the state management unit 81) can perform control (management) corresponding to the changed configuration.
Further, the state holding memory 82 or at least the program holding memory 82a is composed of, for example, a non-volatile and electrically rewritable flash memory or EEPROM, and the program data can be easily changed via the state management unit 81. I have to.

For example, a command for changing program data is sent to the state management unit 81 via the signal line 71b, that is, via the following wired transmission / reception unit 83, and program data to be rewritten after the command is sent from the AWS unit 4 side. By doing so, the program data can be changed. In addition, version upgrade or the like can be easily performed via the signal line 71b.
In addition, model information unique to each endoscope 3 and individual information corresponding to the use state may be written and held in the state holding memory 82 as described below so that the information can be used effectively. Specifically, the state holding memory 82 holds, for example, model information of the endoscope 3 (for example, information on the type of the CCD 25, the length of the insertion portion, etc.), and the internal information that varies depending on usage conditions such as endoscopy. Individual information of the endoscope 3 (for example, information such as usage time (total time of endoscopy or total usage time), number of cleanings, adjustment value, maintenance history, etc.) is stored, and these information are used to determine system operation. Used to provide information to users and users.
These pieces of information can be edited from the outside such as the endoscope system control device 5 and a cleaning device (not shown).
By doing so, information (data) held in the scope ID can be effectively used by sharing and using the state holding memory 82 by combining the function of the conventional scope ID.
Further, since this state holding memory 82 is provided, it is not necessary to provide a separate scope ID, and it is possible to make it more functional than the existing scope ID, and to perform appropriate settings, adjustments, management, processing, etc. in more detail. Is possible.

  The state management unit 81 is connected to a wired transmission / reception unit 83 (in this embodiment) that communicates with the AWS unit 4 by wire (this transmission / reception unit 83 corresponds to FIG. 2B). 2 (B), the electrical connector 15 is a contactless transmission unit 72a, 72b in the operation unit 22 and an electrical component at the end of the tube unit 19. Connector 74).

Moreover, this state management part 81 controls the LED drive part 85 controlled by this illumination control part 84 via the illumination control part 84 which controls illumination. The LED drive unit 85 applies an LED drive signal for causing the LED 56 serving as an illumination unit to emit light.
The illuminated object such as an affected part is imaged on the imaging surface of the CCD 25 arranged at the imaging position by the objective lens 169 attached to the observation window, and photoelectrically converted by the CCD 25. .
The CCD 25 outputs signal charges accumulated by photoelectric conversion as an imaging signal by application of a CCD drive signal from a CCD drive unit 86 controlled by the state management unit 81. The imaging signal is converted from an analog signal to a digital signal by an A / D converter (abbreviated as ADC) 87 and then input to the state management unit 81, and the digital signal (image data) is stored in the image memory 88. The The image data in the image memory 88 is sent to the data transmission unit 12 ′ of the transmission / reception unit 83.

Then, the signal is transmitted from the electrical connector 15 (contactless transmission unit 51b in this embodiment) to the AWS unit 4 side through the signal line 73b in the tube unit 19. Further, the data is transmitted from the AWS unit 4 to the endoscope system control device 5 wirelessly.
The output signal of the ADC 87 is sent to the brightness detection unit 89, and the brightness information of the image detected by the brightness detection unit 89 is sent to the state management unit 81. Based on this information, the state management unit 81 performs dimming control through the illumination control unit 84 so that the amount of illumination light from the LED 56 has an appropriate brightness.
As will be described below, when the optical pressure detection operation is performed, the dimming control is performed so that the illumination light amount of the LED 56 is kept constant, and an image with an appropriate brightness by changing the gain of the CCD 25 is obtained. To be obtained.

  As described above, in this embodiment, the contact sensor 142 is provided on the outer peripheral surface of the distal end portion 24, and the contact sensor 142 performs contact detection (press detection) based on the detection output thereof. It is connected to the state management unit 81 via 147.

Then, when the angle operation is performed, the state management unit 81 performs control to restrict the bending of the bending unit 27 based on the detection result by the contact sensor 142 at that time. By performing this control, the bending portion 27 is reduced so as not to apply more force than necessary to the inner wall of the body cavity. For example, when the insertion portion 21 is inserted into the body cavity, the pain given to the patient is reduced. To ensure smooth insertion.
In addition, the state management unit 81 controls the actuator driving unit 92 via the angle control unit 91 and manages the driving of the angle actuator (EPAM) 27a by the actuator driving unit 92. The driving amount of the angle actuator (EPAM) 27a is detected by the encoder 27c, and the driving amount is controlled so as to coincide with the value corresponding to the instruction value.

In addition, the state management unit 81 controls the actuator driving unit 94 via the hardness variable control unit 93 and performs management for driving the hardness varying actuator 54 by the actuator driving unit 94. The driving amount of the hardness varying actuator 54 is detected by the encoder 54c and controlled so that the driving amount becomes a value corresponding to the instruction value.
In addition, an operation signal corresponding to an operation amount from a trackball 69 or the like provided in the operation unit 22 is input to the state management unit 81 via the trackball displacement detection unit 95.
In addition, an operation of pressing a switch such as ON by air / water supply SW, suction SW, or scope SW is detected by the switch press detection unit 96, and the detected information is input to the state management unit 81. EPAM has a characteristic of generating an electromotive force by deformation due to an external force, and EPAM arranged on the opposite side of the driven EPAM may be used as an encoder.
The control circuit 57 includes a power transmission / reception unit 97 and a power generation unit 98. Specifically, the power transmission receiving unit 97 is a contactless transmission unit 72 a in the operation unit 22. The AC power transmitted to the power generation unit 98 is converted into a DC power by the power generation unit 98. The power supply generation unit 98 corresponds to the power supply circuit 78 in FIG. The DC power generated by the power generator 98 supplies power necessary for its operation to each part in the control circuit 57.

FIG. 16 shows an internal configuration of the transmission / reception unit 101 and the image processing unit 116 of FIG. 8 in the endoscope system control apparatus 5.
The endoscope system control device 5 includes a wireless transmission / reception unit 101, for example. Data such as an image signal transmitted wirelessly from the AWS unit 4 is captured by the antenna unit 13, sent to the data receiving unit 14, amplified, and demodulated. The operation of the data receiving unit 14 is controlled by the data communication control unit 11, and the received data is sequentially stored in the buffer memory 102.
The image data in the buffer memory 102 is sent to the image processing unit 103 that processes the image data. In addition to the image data from the buffer memory 102, the image processing unit 103 also receives character information from the character generation unit 105 that generates character information by key input on the keyboard 104, and superimposes the character information on the image data. You can pose.

The image processing unit 103 sends the input image data and the like to the image memory control unit 106, temporarily stores the image data and the like in the image memory 107 via the image memory control unit 106, and records them on the recording medium 158.
The image memory control unit 106 reads the image data temporarily stored in the image memory 107 and sends the image data to the digital encoder 108. The digital encoder 108 encodes the image data in a predetermined video format, and the D / A converter ( (Abbreviated as DAC) 109. The DAC 109 converts a digital video signal into an analog video signal. The analog video signal is further output from the video output end to the observation monitor 6 via the line driver 110, and an image corresponding to the video signal is displayed on the observation monitor 6.
The image data temporarily stored in the image memory 107 is read out and input to the DV data generation unit 111. The DV data generation unit 111 generates DV data, and the DV data is output from the DV data output terminal. Is done.

In addition, the endoscope system control device 5 is provided with a video input end and a DV data input end, and a video signal input from the video input terminal is converted into a digital signal via the line receiver 112 and the ADC 113. The video signal is demodulated by the digital decoder 114 and input to the image memory control unit 106.
The DV data input to the DV data input terminal is extracted (decoded) by the image data extraction unit 115 and input to the image memory control unit 106.
The image memory control unit 106 also temporarily stores the video signal (image data) input from the video input terminal or the DV data input terminal in the image memory 107, records it in the recording medium 158, or outputs the video signal. Or output to the observation monitor 6 from the end.
In the present embodiment, image data captured by the CCD 25 of the endoscope 3 and UPD image data generated by the UPD unit 76 are wirelessly input to the endoscope system control device 5 from the AWS unit 4 side. The endoscope system control device 5 converts these image data into predetermined video signals and outputs them to the observation monitor 6. The endoscope system control device 5 may receive UPD coil position data instead of UPD image data, and generate UPD image data in the image processing unit 103.

FIG. 17 shows the internal configuration of the AWS unit 4.
Image data input from the control circuit 57 of the endoscope 3 to the electrical connector 43 for the scope and operation data such as a switch are output to the data communication control unit 11 of the transmission / reception unit 77, and UPD image data from the UPD unit 76. At the same time, the signal is transmitted from the antenna unit 13 to the antenna unit 13 of the endoscope system control device 5.
On the other hand, the AWS related information such as the operation of the air / water supply switch and the suction switch provided in the operation unit 22 of the endoscope 3 is also sent to the air / water supply control unit 122. The operations of the pump 65 and the solenoid valve unit 124 are controlled in accordance with the information thus obtained.
The electromagnetic valve unit 124 is connected with air / water supply pipelines 60 b and 61 b via the AWS adapter 42. Further, a water supply tank 48 is connected to the electromagnetic valve unit 124 and the AWS adapter 42, and a suction tank 49 b is connected to the AWS adapter 42.

Also, commercial power is supplied to the AWS unit 4, and this commercial power is sent to the power transmission output unit 127 via the insulation transformer 126. The power transmission output unit 127 supplies an AC power source insulated from a commercial power source from the electrical connector 43 to the power source line 73 a of the endoscope 3 connected to the electrical connector 43.
The power transmission output unit 127 has its power transmission output controlled by a power transmission control unit 128 connected to the data communication control unit 11.
In the endoscope system 1 including the present embodiment, when the power is turned on, various images are displayed on the observation monitor 6 as shown in FIG. 18A, for example. In this case, in addition to the information display area Rj for displaying patient information and the like, the endoscope image display area Ri, the UPD image display area Ru, the freeze image display area Rf, and the angle-shaped display area Ra, the menu display area Rm is provided, and a menu is displayed in the menu display area Rm. The angle-shaped display area Ra detects the angle operation amount of the angle actuator 27a by the encoder 27c and displays the angle shape in that case.

As a menu displayed in the menu display area Rm, a main menu shown in FIG. 18B is displayed. This main menu includes a scope switch, angle sensitivity, insertion section hardness, zoom, image enhancement, air supply amount, and an instruction to return to the previous menu screen. Is displayed.
Then, when the user moves and selects the selection frame to the scope switch item by operating the track ball 69 or the like, the frame of the scope switch item is displayed thickly to indicate that it has been selected. By pressing and performing the determination operation, it is possible to select and set the function assigned to the five scope switches SW1 to SW5 as shown in FIG.

Next, the operation of the endoscope system 1 having such a configuration will be described.
As a preparation for carrying out the endoscopic examination, first, the general connector part 52 on the disposable tube unit 19 side is connected to the connector part 51 of the operation part 22 of the endoscope body 18. In this case, the transformers T1 and T2 forming the contactless transmission units 72a and 72b are electromagnetically connected to each other in an insulated and waterproof state. With this connection, the preparation of the endoscope 3 is completed.
Next, the scope connector 41 of the tube unit 19 is connected to the connector 43 of the AWS unit 4. This part is completed by a single connection operation by various connection lines, power lines, signal lines, and optical connections by one-touch connection. There is no need to connect various pipes or electrical connectors each time as in a conventional endoscope system.

The user connects the AWS unit 4 to the UPD coil unit 8 and connects the endoscope system control device 5 to the observation monitor 6. Further, the setup of the endoscope system 1 is completed by connecting the endoscope system control device 5 to the image recording unit 7 or the like as necessary.
Next, the power of the AWS unit 4 and the endoscope system control device 5 is turned on. Then, each part in the AWS unit 4 is in an operating state, and the power supply unit 75 can supply power to the endoscope 3 side via the power supply line 73a and the like.
Operations at the time of starting the AWS unit 4 and the endoscope 3 in this case will be described with reference to FIGS. 19 and 20.

When the power transmission control unit 128 in the power supply unit 75 of the AWS unit 4 shown in FIG. 17 starts the activation process, the power transmission output unit 127 is supplied with power in the first step S1, as shown in FIG. Stop, that is, turn off the power supply.
Thereafter, in step S2, after the monitoring timer is turned on, the power transmission output unit 127 is turned on, that is, the power supply is turned on, as shown in step S3. When the power transmission output unit 127 is in a state of supplying power, the power is transmitted through the power line 73a in the tube unit 19 and further through the contactless transmission unit 72a, and the power generation unit in the control circuit 57 of the operation unit 22 AC power is supplied to 98.
Thereafter, as shown in step S <b> 4, the power transmission control unit 128 waits to receive an activation message from the endoscope 3 side via the signal line 73 b in the tube unit 19. If the power transmission control unit 128 does not receive the activation message, the power transmission control unit 128 determines whether or not the monitoring timer has expired as shown in step S5. If not, the process returns to step S4. In this case, the process returns to the first step S1.

On the other hand, when the activation message is received before the time expires in step S4, the power transmission control unit 128 turns off the time measurement of the monitoring timer as shown in step S6. Then, a continuation message is issued as shown in step S7, and this activation process is terminated.
On the other hand, the control circuit 57 of the endoscope 3 is supplied with AC power to the power generation unit 98, so that the power necessary for the operation in the control circuit 57 is supplied and starts the startup process. Then, the state management unit 81 shown in FIG. 15 waits for the power supply voltage of the power generation unit 98 to be stabilized in the first step S11.
When the power supply voltage is stabilized, the state management unit 81 performs system initialization of each unit of the control circuit 57 in the next step S12. After this system initialization, as shown in step S13, the state management unit 81 transmits an activation message to the power transmission control unit 128 via the transmission / reception unit 83 and further via the signal line 73b in the tube unit 19.

After the activation message is transmitted, the state management unit 81 waits to receive a continuation message from the power transmission control unit 128 as shown in step S14. If the continuation message is received, the activation process is performed. finish. On the other hand, when the continuation message is not received, as shown in step S15, the state management unit 81 returns to step S13 when the retry end condition (for example, the preset number of retry conditions) is not reached. If the start message is issued again and the retry condition is met, the process ends in error.
When the activation process ends normally, imaging by the CCD 25 starts, and the user can perform air / water feeding, suction, angle operation, hardness variable operation, and the like by the operation means of the operation unit 22.
In this embodiment, as described below, the output of the optical pressing amount detection means is used for angle operation so that the insertion operation of the insertion portion 21 can be performed smoothly.

The angle operation control process will be described with reference to FIG. When the angle control process starts, the state management unit 81 determines whether or not the angle control is valid as shown in step S41.
In the present embodiment, depending on whether or not the trackball 69 is pressed against the trackball 69, the state management unit 81 determines whether or not the angle control is valid as shown in step S41. Specifically, the state management unit 81 can detect the displacement operation and the pressing operation of the trackball 69 based on the output of the trackball displacement detection unit 95. When the trackball 69 is pressed, the angle control is turned off.
The state management unit 81 determines whether or not the angle control is valid based on the output of the trackball displacement detection unit 95.

If it is determined that the angle control is not effective, the process proceeds to step S45, and the previous command value is held. On the other hand, if it is determined that the angle control is valid, the process proceeds to the next step S42, and the state management unit 81 acquires the state data by operating the trackball 69. Then, in the next step S43, the state management unit 81 determines whether or not there is a further state change based on the output of the trackball displacement detection unit 95.
In this case, if the state management unit 81 determines that there is no state change, the process proceeds to step S45. Conversely, if it is determined that there is a state change, the rotation direction of the trackball 69 is determined in the next step S44. The command value corresponding to the rotation amount is calculated.
After the processing of step S44 or S45, as shown in step S46, the state management unit 81 sends the command value to the actuator driving unit 92 via the angle control unit 91 and performs servo processing on the angle actuator 27a.

  That is, the actuator driving unit 92 drives the angle actuator so as to be in an angle state (curving angle) corresponding to the command value based on the command value.

In addition, during the start of the servo processing in step S46, the state management unit 81 captures the detection result by the contact sensor 142 through the contact sensor detection unit 147 as shown in step S47, so that the distal end portion 24 becomes the body cavity. It detects (determines) whether it is in contact with the inner wall or the like at a pressure higher than an appropriate value.
If the state management unit 81 determines that the contact is not made at an appropriate value or more, the state management unit 81 proceeds to the next step S48, and determines whether or not the target position corresponding to the angle command value has been reached by the encoder 27c. If the target position has not been reached, the process returns to step S46. If the target position has been reached, the control process for this angle operation is terminated.
On the other hand, in step S47, when the state management unit 81 determines that the contact is made at an appropriate value or more, the control process for the angle operation is terminated without performing the process of the next step S48.

As described above, when the angle operation is performed, the state management unit 81 performs the control process so as to bend the bending portion 27 to the target position corresponding to the command value by the angle operation. If the inner wall or the like in the body cavity is contacted with a pressure equal to or higher than the determined value, control is performed so as to suppress further bending.
Accordingly, when the user inserts the insertion portion 21 into the body cavity, even when the user performs an angle operation in order to insert the insertion portion 21 along the bent duct, the contact is made at a pressure higher than the set value. Therefore, the pain given to the patient can be further reduced and smooth insertion can be achieved.
According to the endoscope 3 of the present embodiment that forms the endoscope system 1 that performs such an operation, pressing amount detection (contact) is performed using a part of light on the peripheral side in the illumination light emitted from the illumination window. Since a means for performing detection) is formed, it can be used to smoothly use the illumination light and smoothly perform insertion work and the like.

  Further, in the endoscope 3 of the present embodiment, the endoscope main body 18 and the tube unit 19 can be separated at the operation unit 22 and the tube unit 19 side is made a disposable type, whereby the endoscope main body. 18 can be easily cleaned and sterilized.

That is, the air / water supply conduit 60a and the suction conduit 61a in the endoscope body 18 can be made much shorter than in the case of the conventional example in which the universal cable corresponding to the tube unit 19 is integrally formed. And easy to sterilize.
Further, in this case, in the case of the conventional example in which the universal cable corresponding to the tube unit 19 is integrally formed, the universal cable is bent from the operation unit 22 and is continuously provided. In the connector part 51 of the operation part 22, the pipe connector part 51a is slightly bent, and the other parts are an air / water supply pipe line 60a and a suction pipe line 61a that extend substantially linearly. It is possible to easily and quickly perform processing such as washing, sterilization, and drying in the road. Therefore, it can be set in a short time so that the endoscopy can be performed.

Further, in this embodiment, since the endoscope body 18 and the tube unit 19 are detachably connected without contact, even if the endoscope body 18 is repeatedly cleaned and sterilized, it is not contactless. In this case, there is no occurrence of contact failure or the like, and reliability can be improved.
In the present embodiment, the operation unit 22 is provided with a number of operation means such as an angle operation means, an air / water supply operation means, a suction operation means, a hardness varying means, a freeze operation means, a release operation means, and the like. The means is configured to be intensively (intensively) controlled by a control circuit 57 provided in the operation unit 22. The control circuit 57 is configured to collectively control the light emitting means for emitting illumination light for performing imaging and the imaging means for performing imaging together with the operation means.
As described above, in this embodiment, various functions provided in the endoscope main body 18 are collectively controlled by the control circuit 57 provided in the operation unit 22, and the AWS unit connected to the endoscope main body 18 is used. 4 and the endoscope system control device 5 that wirelessly transmits and receives information are configured to collectively control various functions with respect to the operation means, so that the user (more specifically, the surgeon) Various operations can be freely performed by the various operation means provided, and the operability can be greatly improved.

Particularly in the present embodiment, by providing a control circuit 57 that performs intensive control in the operation unit 22, image data obtained by the CCD 25 from the control circuit 57 and various signals from the operation means are packetized. For example, the number of electric signal lines can be reduced (specifically, two signal lines for transmitting signals and a power line 2 for transmitting power). In addition, if one of the signal line and the power supply line is used in common, the number can be reduced to three as a whole).
Therefore, it is possible to reduce the number of signal lines that need to be inserted into the tube unit 19 connected at the connection portion in the operation portion 22, and to make the tube unit 19 side disposable.
Further, by reducing the number of signal lines inserted into the tube unit 19, the tube unit 19 can be easily reduced in diameter and bent, and the operability when the user operates can be improved.

Next, Embodiment 2 will be described with reference to FIGS. FIG. 22 shows a part of the insertion portion 21 in the endoscope 3B of the second embodiment.
In the endoscope 3 according to the first embodiment shown in FIG. 9, the contact sensors 142a to 142d are provided at the upper, lower, left and right positions on the periphery of the distal end portion 24. However, in the endoscope 3B according to the present embodiment, the bending portion is further provided. Contact sensors 171a to 171d and 172a to 172d are also provided in the vicinity of the rear end of 27 and on the rear side of the curved portion 27.
For example, the contact sensors 171a to 171d have the following configuration.
Inside the vicinity of the rear end of the curved portion 27, an LED 173 and a light detection element array 174 are arranged, and the light of the LED 173 is guided into the pressing deformation member 176i by the optical fiber 175i, and also inside the pressing deformation member 176i. One end of a pair of optical fibers 177i is disposed in the. The light detected by the optical fiber 177 i is received by the light detecting element array 174.

The LED 173 and the light detection element array 174 are connected to the control circuit 57 by signal lines. Since the contact sensors 172a to 172d have the same configuration, the description thereof is omitted. In this embodiment, it is possible to detect a state in which the peripheral edge portion (specifically, the vertical and horizontal positions) of the distal end portion 24 is in contact with the inner wall of the body cavity and is pressed and deformed. It is possible to detect a state where the pressure is deformed at each of the upper, lower, left and right positions and a state where the pressure is deformed at each of the upper, lower, left and right positions on the outer peripheral surface behind the bending portion 27.
Also in this embodiment, when the detection output of the contact sensors 142a to 142d, 171a to 171d, and 172a to 172d is input to the control circuit 57 and the bending portion 27 is bent, the pressing amount is detected. By restricting the bending to the side where stagnation is detected, smooth insertion or the like can be performed.

In the present embodiment, as in the first embodiment, in addition to the contact sensors 142a to 142d, the distal end portion 24 is provided in the vicinity of the rear end of the bending portion 27 and further on the rear end side. The pressing state at can be detected. The other effects are the same as those of the first embodiment.
In FIG. 22, a light source for detecting a pressing amount different from that of the LED 56 that generates illumination light is used. However, a structure in which the pressing amount is detected using the light on the peripheral side of the light flux by the LED 56 is used. You can also.
FIG. 23 shows the structure of the distal end side of the endoscope 3C of the first modification. In the present modification, for example, in the configuration of FIG. 22, contact sensors 197 a to 197 d are further arranged, for example, at four locations on the inside and the upper and left and right sides of the bending portion 27. FIG. 23 shows the upper and lower contact sensors 197a and 197c.

And it is utilized for the detection means which detects the bending state of the up-and-down and left-right of the bending part 27 by the output of each contact sensor 197j.
That is, when the bending portion 27 is bent downward, for example, a pressing force that crushes the contact sensor 197a inside the bending portion 27 acts, so that a change in the detected light amount occurs, and the bending amount (curving amount) The amount of bending can be detected by examining the relationship between the angle) and the change in the amount of light and referring to the data.
FIG. 24 shows the shape of the distal end side of the insertion portion 21 of the endoscope 3D of the second modification. In this modification, a tapered portion 181 is provided on the peripheral edge portion of the distal end portion 24. In addition, a hard large-diameter portion 182 that is thicker than the outer diameter of the insertion portion 21 is provided at the rear end portion of the curved portion 27.

FIG. 25 shows the internal structure of the distal end side of the insertion portion 21 of the endoscope 3D. In this modification, an LED 184 for illumination is provided in the hard large-diameter portion 182, and the illumination light of the LED 184 is transmitted by the light guide fiber bundle 185 in which the rear end (incident end) is disposed so as to face the LED 184. The light is further emitted forward from the front end surface fixed to the illumination window of the front end portion 24 via the illumination lens 186.
Also, light guide fibers 187a, 187b, 187c, and 187d are arranged in a ring shape on the outermost periphery of the light guide fiber bundle 185 so that part of the illumination light of the LED 184 is incident thereon.
And the illumination light of LED184 entered by the rear end of each light guide fiber 187j is guided, and it radiate | emits from a front end surface. The distal end of each light guide fiber 187j is disposed inside a circular ring-shaped pressing deformation member 188 disposed in the tapered portion 181 of the distal end portion 24, and emits the guided light.

FIG. 26A shows the light guide fiber 187j (and 189j) arranged inside the circular ring-shaped pressing deformation member 188 along the line DD 'in FIG. Note that, as shown in FIG. 26B, the light guide fibers 187 (and 189) may be provided in directions other than the vertical and horizontal directions.
Inside the pressing deformation member 188, the front end surface of the light guide fiber 189j that is paired with each light guide fiber 187j is arranged, and the light reflected and incident by the pressing deformation member 188 is guided to the rear end. At the rear end, a photodetecting element array 190 is disposed, and the guided light is received and photoelectrically converted. The outer periphery of the pressing deformation member 188 is covered with a protection member 191.
In the present modification, for example, a reference pressure deformation member 192 having substantially the same shape and the same characteristics as the pressure deformation member 188 is disposed in the hard large-diameter portion 182. Further, the pressing deformation member 192 is set in a state where it is not deformed.
The light guide fiber 185 is guided to the inside of the press deformation member 192 using the light guide 193j on the outermost periphery of the light guide fiber bundle 185. The light guide 194j paired with the light guide 193j guides the light to the light detection elements of the light detection element array 190.
The light guided by the light guide 194j is used as a reference (reference), and the amount of change from the photoelectric conversion output value in the case of the light is detected, so that pressing (contact) can be detected with high accuracy. ing.

It should be noted that the reference side optical fibers 193j and 194j may have only one pair and may have a simplified configuration. In this case, the pressing deformation member 192 may be provided only in the vicinity of the reference optical fibers 193 and 194 instead of being provided in a circular ring shape like the pressing deformation member 188.
According to this modification, the pressing amount can be detected with higher accuracy.
It should be noted that embodiments configured by partially combining the above-described embodiments and the like also belong to the present invention.

[Appendix]
1. In Claim 1, the said press deformation member is provided in the multiple places of the longitudinal direction of the insertion part in the peripheral part including the said bending part.
2. In Claim 1, the said press deformation member is provided in the multiple places of the circumferential direction of the insertion part in the peripheral part including the said bending part.
3. In Claim 1, it has a judgment means which judges whether the press amount more than predetermined value acted from the output signal by the said light detection means.
4). In Claim 1, It has a control means which controls the curve of the said bending part by the change of the output signal by the said photon detection means.
5. In Claim 1, The said 1st light guide means has a light branching means in order to take in a part of said illumination light.

6). The amount of change from the reference value according to claim 1, wherein the reference member having substantially the same characteristics as the pressing deformation member is not deformed, and the light detection means uses the detection output of light guided from the reference member as a reference value. Thus, a pressing amount acting on the pressing deformation member is detected.

7). A first step of driving the bending portion to bend in the direction of the bending instruction according to the bending instruction;
A second step of detecting whether or not an output change of the pressing amount detection for optically detecting the pressing amount, which is disposed in a peripheral portion of the bending portion at the time of the bending driving, is greater than or equal to a reference value;
A third step of restricting the bending drive when an output change of the pressing amount detection is equal to or greater than a reference value;
A bending drive control method comprising:

  According to the present invention, when the insertion portion of the endoscope is inserted into the body cavity, the amount of pressing can be detected when it is pressed against the lumen portion. It can be performed.

1 is a schematic configuration diagram of an endoscope system including the present invention. The figure which shows a data communication form. The figure which shows the schematic structure of the endoscope of this invention. The perspective view which shows the whole structure of the endoscope system provided with the present Example. The perspective view which shows the concrete external appearance shape of an AWS unit periphery part. The perspective view which shows the state which attached and removed the AWS adapter which can be attached or detached to an AWS unit. The figure which shows the structure of the connection part of an internal structure of an endoscope system control apparatus and an AWS unit, and a scope connector. The figure which shows the structure of an AWS adapter. 1 is an overall view showing a detailed configuration of an endoscope according to Embodiment 1. FIG. The figure which shows the structure of the front end side of an insertion part. The figure which shows the schematic structure of an optical press amount detection means. Explanatory drawing for showing the rough function of the conductive polymer artificial muscle (EPAM) used for the member for angles and the actuator for variable hardness. The figure which shows the track ball etc. which were provided in the operation part by A arrow view of FIG. The circuit diagram which shows the structure of the contactless transmission part by which the base end of a tube unit is detachably connected to an operation part main body without a contact. The block diagram which shows the structure of the electric system in the component provided in the endoscope. The block diagram which shows the structure of the electrical system of the principal part of an endoscope system control apparatus. The block diagram which shows the structure of the electrical system of an AWS unit. The figure which shows the typical display example of the monitor display surface of an observation monitor, and the specific example of a menu display. The flowchart figure which shows the operation | movement content of the starting process of an AWS unit. The flowchart figure which shows the operation | movement content of the starting process of an endoscope. The flowchart figure which shows the control processing of angle operation. The figure which shows the structure of the insertion part of the endoscope of Example 2 of this invention. The figure which shows the structure of the insertion part of the endoscope of a 1st modification. The figure which shows the external shape of the insertion part of the endoscope of a 2nd modification. The figure which shows the structure of the insertion part of the endoscope of a 2nd modification. The figure which shows the structure of a press deformation member by the DD 'line cross section in FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Endoscope system 2 ... Examination bed 3 ... Endoscope 4 ... AWS unit 5 ... Endoscope control system 6 ... Observation monitor 7 ... Image recording unit 8 ... UPD coil unit 9 ... LAN
DESCRIPTION OF SYMBOLS 11 ... Data communication control part 13 ... Antenna part 15 ... Electric connector 18 ... Endoscope main body 19 ... Tube unit 21 ... Insertion part 22 ... Operation part 25 ... CCD
27 ... Bending part 27a ... Angle actuator 40, 41 ... Scope connector 42 ... AWS adapter 43 ... Electrical connector 44 ... Air supply connector 45 ... Pinch valve 51 ... Connector part 52 ... General connector part 53 ... Soft part 54A. 54B ... Hardness variable actuator 56 ... LED
57 ... Control circuit 58 ... UPD coil 59 ... UPD coil drive unit 60a, 60b ... Air supply / water supply line 61a, 61b ... Suction line 66 ... AWS control unit 68 ... Holding part 69 ... Track ball 72a, 72b ... Contactless transmission Reference numeral 76: UPD unit 77, 83: Transmission / reception unit 81: State management part 82 ... State holding memory 91 ... Angle control part 92 ... Actuator drive part 95 ... Trackball displacement detection part 142 ... Contact sensor 161 ... Optical element 162 ... Illumination lens 163: Optical branching portion 164a, 166a ... Optical fiber 165a ... Pressing deformation member 167 ... Photodetecting element array Agent Patent attorney Susumu Ito

Claims (5)

In an endoscope in which a distal end portion provided with an illumination window and an observation window and a bendable bending portion are provided in the insertion portion,
First light guiding means for guiding a part of the illumination light to be emitted from the illumination window to the peripheral portion including the curved portion;
A pressure deforming member disposed at least in the peripheral portion including the curved portion, the light guided by the first light guide means being emitted to the inside, and the shape changing according to the amount of pressure from the outside; ,
A second light guide means for receiving and guiding the light emitted into the pressing deformation member;
Light detection means for detecting light guided by the second light guide means;
An endoscope characterized by comprising:   The endoscope according to claim 1, wherein the first light guide unit guides illumination light on a peripheral side in illumination light emitted from the illumination window.   The endoscope according to claim 1, wherein the first and second light guide means are configured using optical fibers.   The endoscope according to claim 1, wherein the pressing deformation member is disposed inside the bending portion, and forms a means for detecting a bending amount of the bending portion.   The first light guiding means is configured by using a light guide fiber disposed on a peripheral side of a light guide fiber bundle that constitutes a light guide that emits illumination light from the illumination window. 1. The endoscope according to 1.

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