JP5541954B2 - Endoscope - Google Patents

Description

  The present invention relates to an endoscope. More specifically, the present invention relates to an endoscope that effectively dissipates heat generated from a heat generating part such as a solid-state imaging device or an illumination part arranged at the distal end of an insertion part to an axial rear end of the insertion part. It relates to the endoscope.

  Conventionally, in the medical field, medical diagnosis using an endoscope, for example, an electronic endoscope has been actively performed. A solid-state imaging device such as a CCD and an illuminating unit that illuminates the inside of the body cavity are incorporated at the distal end of the insertion part that is inserted into the body cavity of the electronic endoscope. The image in the body cavity can be observed on a monitor by performing various signal processing on the imaging signal output from the CCD with a processor device.

  The tip of the insertion portion sometimes becomes a high temperature of 40 ° C. or higher due to the driving heat of electronic components such as a CCD. When the temperature at the tip of the insertion part rises, condensation occurs on the cover glass that protects the CCD due to the temperature difference between the surface and the inside of the tip of the insertion part caused by water or air that cleans the tip of the insertion part. The signal line is heated and the signal is deteriorated, so that the image quality is remarkably deteriorated and observation becomes difficult. In addition, there is a possibility of exceeding 41 ° C. required by JIST 0601-2-18. Based on such a background, various measures have been taken to suppress the temperature rise at the tip of the insertion portion (see Patent Documents 1 and 2).

  The technique described in Patent Document 1 is such that an objective optical system, a CCD, an electronic component, a circuit board, and the like constituting a solid-state imaging device are disposed inside a shield frame filled with heat-radiating silicon having high thermal conductivity, and an insertion portion It is generated at the tip of the insertion part by filling the heat dissipation and highly viscous second heat dissipation silicon from the through hole of the bending piece connected to the back of the tip of the, and covering the vicinity of the solid-state imaging device with the second heat dissipation silicon Heat is transmitted to the bending piece to radiate heat.

  In Patent Document 2, a part of a heat radiating member made of a metal material is embedded in a ceramic package in which electronic circuit components and a circuit board constituting a driving circuit of a solid-state imaging device are collectively sealed with a ceramic material. A distal end portion of an electronic endoscope in which this portion is exposed to a space in the insertion portion is disclosed.

  Patent Document 3 discloses an endoscope using a heat conductive material in which one end is attached to a heat generating portion at the distal end of the insertion portion and the other end is located on the rear end side of the insertion portion. The heat conduction material is made of a sheet-like film, and in addition to tubes and cables inserted in the axial direction of the insertion portion, forceps channels, air supply / water supply tube nozzles, and tubulars such as operation wires It is wound around the member.

JP-A-6-327626 JP 2005-348846 A JP 2009-56107 A

  In the inventions described in Patent Documents 1 and 2, although the heat of the part that generates heat is absorbed, the surroundings are heated by the heat transmitted to the heat dissipation silicon and the heat dissipation member, and eventually the temperature around the heat generation part rises. End up. In other words, even if heat is taken away from the heat generating portion, the heat taken away in the vicinity is dissipated, so that the heat generating portion expands.

  In the invention described in Patent Document 3, the film itself, which is a heat conductive material, has high thermal conductivity, but the tubular member that contacts this and transfers heat axially rearward of the insertion portion has high thermal conductivity. Even if it is made of a material, it contains other materials in order to give it a property with high elasticity and tensile strength, so that the thermal conductivity may be inferior to that of a single thermal conductive material. For this reason, heat cannot be transferred quickly to the rear in the axial direction.

  Here, various attempts have been made to reduce the diameter of the insertion portion of the electronic endoscope in order to reduce the burden on the patient. Recently, the electronic endoscope is inserted through the nostril. An electronic endoscope having a thin insertion portion such as an endoscope has been developed. However, if the diameter of the insertion portion is reduced, the heat capacity at the distal end of the insertion portion is reduced, and therefore the temperature at the distal end of the insertion portion is likely to increase.

  Conventionally, xenon lamps and metal halide lamps have been used as the light source of the illuminating unit that illuminates the body cavity. It is becoming active. When a light emitting diode or semiconductor laser is used as the light source, the amount of heat generated in the illumination unit increases. Furthermore, the driving heat of the solid-state image sensor and the circuit board is steadily increasing due to the increase in the circuit processing load accompanying the increase in the number of pixels of the solid-state image sensor and the burden of digitizing the image signal from the solid-state image sensor. Tracing. For this reason, the development of a technique that effectively and quickly suppresses the temperature rise at the distal end of the insertion portion is not only an urgent task but also the most important issue throughout the future of electronic endoscopes.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide an endoscope that can quickly and effectively suppress the temperature rise at the distal end of the insertion portion.

In one embodiment of the endoscope of the present invention, the operation portion main body having operation knob, a pulley for pushing and pulling the manipulation wire in conjunction with the operation of the operation knob is incorporated in the operation portion main body, provided in the operation portion main body and a tip portion having a built-in bend and the heating element is bent in conjunction with the pushing and pulling of the operation wire is provided on the distal end side of the flexible portion against the elongated flexible portion and the operation portion main body which is insertion portion and in contact with the heat transfer member which connects the the operating wire disposed within the earlier end heating element, axially rearward operation wire insertion portion with respect to curved portion or curved portions thermal conductivity A heat dissipating member made of a material having a high rate characteristic, and the operation wire has a cylindrical shape having a diameter of 0.5 to 0.05 mm using a carbon nanotube or a composite material mainly composed of carbon nanotube Is made.

The endoscope according to the present disclosure can quickly and effectively suppress the temperature rise at the distal end of the insertion portion .

It is a perspective view which shows the endoscope system using this invention. It is sectional drawing of a soft part. It is explanatory drawing which shows the front end surface of a front-end | tip part. It is sectional drawing of a front-end | tip part. It is explanatory drawing which shows roughly winding of the operation wire of an endoscope. It is explanatory drawing which shows the pulley connected with the operation knob. It is a perspective view which shows the supporting member which guides the connection member of an operation wire. It is explanatory drawing which shows the relationship between rotation of a pulley, and pushing and pulling of an operation wire, (A) is an initial state, (B) is a moving direction of a connection member when an operation knob is rotated to one side, (C) is an operation knob. The direction of movement of the connecting member when rotating to the other is shown.

As shown in FIG. 1, the endoscope system 10 includes an endoscope 11, a light source device 13, a processor device 14, a monitor 15, and the like. The endoscope 1 1 has an insertion portion 16 to be inserted into a body cavity. A gripping portion 17 is connected to the proximal end portion of the insertion portion 16, and a hand operating portion 18 is attached to the gripping portion 17. A universal cable 20 is provided in the hand operation unit 18, and a universal connector 19 connected to the light source device 13 and the processor device 14 is attached to the distal end of the universal cable 20.

  The insertion portion 16 is provided with a forceps conduit in an internal space penetrating from the distal end to the gripping portion 17. One end of the forceps conduit is connected to a forceps outlet provided at the distal end, and the other end is connected to a forceps inlet 21 provided at the gripping portion 17. The grip part 17 and the hand operation part 18 constitute an operation part main body 22.

  As is well known, the insertion portion 16 includes a distal end hard portion 23, a bending portion 24, and a soft portion 25. Note that the distal end hard portion 23 and the curved portion 24 constitute the distal end portion 26 of the insertion portion 16 of the endoscope 11 of the present invention.

  The distal end hard portion 23 is formed of a hard metal material or the like, and includes an observation optical system, an image sensor, an illumination optical system, and the like. The universal connector 19 includes a light guide LG connector 27 and an electrical connector 29 provided at the tip of a cord 28 extending therefrom. The electrical connector 29 is connected to the processor device 14, and the LG connector 27 is connected to the light source device 13.

  The processor device 14 is provided with an image processing circuit or the like for performing image processing on an image pickup signal obtained from the image pickup device and encoding it into a composite signal or an RGB component signal. The light source device 13 has a built-in light source lamp, and the light passes from the hand operating portion 18 to the distal end portion 26 by the light guide (fiber bundle) accommodated in the internal space of the insertion portion 16. It is guided and enters the illumination optical system.

  The flexible portion 25 is a portion that connects the hand operating portion 18 and the bending portion 24 in a narrow shape with a long diameter, and has flexibility. The hand operating section 18 is provided with two operation knobs 30 and 31 for up and down and left and right. The bending portion 24 incorporates a connecting piece row in which a plurality of connecting pieces are connected. In conjunction with the operation of the two operation knobs 30 and 31, the operation wire accommodated in the internal space of the insertion portion 16 is pushed and pulled, and the connecting piece row is bent. As a result, the distal end surface 33 of the distal end hard portion 23 faces in a desired direction within the body cavity, so that a desired observation site can be observed. The observation site is illuminated with light emitted from the illumination optical system, and the reflected light is imaged by the imaging device via the observation optical system and displayed on the monitor 15 via the image processing circuit.

  In addition to the two operation knobs 30 and 31 and the forceps inlet 21 described above, the hand operating unit 18 is provided with an air / water supply button 34, a suction button 35, a water jet port (WJ port) 36, and the like. The WJ port 36 is detachably connected to a syringe, a water supply device, and the like that contain a fluid such as cleaning water or a chemical solution that is jetted toward the site to be observed. Note that the WJ port 36 and the forceps inlet 21 are usually closed by a detachable stopper.

  As shown in FIG. 2, the flexible portion 25 of the endoscope 11 includes a flexible tube 40 including three layers of a screw tube 37, a net 38, and an outer layer 39 in order from the inside. The screw tube 37 protects the inside while maintaining flexibility, and is generally called a flex. The net 38 is coated on the screw tube 37 and holds the resin of the outer layer 39 and is generally called a blade. The outer layer 39 is made by depositing a resin on the net 38.

  Inside the flexible portion 25, light guides 41 and 42 for guiding illumination light to the illumination optical system of the distal end hard portion 23, operation wires 43 to 46, forceps conduit 47, air / water supply conduit 48, many A plurality of contents such as a core cable 49 and a water jet pipe (WJ pipe) 50 are loosely inserted. The multi-core cable 49 is a cable for mainly sending a signal for driving the imaging device from the video signal processing unit and sending an imaging signal obtained from the imaging device to the video signal processing unit. The cross-sectional shape is covered with a protective coating. The operation wires 43 to 46 are hung around two pulleys interlocking with the operation of the operation knobs 30 and 31 by inserting two wires for up and down and left and right, respectively, and their tips are inserted toward the bending portion 24. Therefore, there are four inside the flexible portion 25, and each is inserted into the close contact coil pipe 51. The four contact coil pipes 51 guide the operation wires 43 to 44 slidably and flexibly between the bending portion 24 and the grip portion 17.

  As shown in FIG. 3, an observation window 52, a pair of illumination windows 53, 54, a water jet nozzle (WJ nozzle) 55, a forceps outlet 56, an air / water supply nozzle 57, etc. Is exposed. In the observation window 52, a part of an objective optical system for taking in image light of a site to be observed in the body cavity is arranged, and an imaging element is built in this bag. The illumination windows 53 and 54 are provided on both sides of the observation window 52, and irradiate light to be observed in the body cavity with the light transmitted from the light source device 13 via the light guides 41 and 42.

  The forceps outlet 56 is communicated with the forceps inlet 21 via a forceps conduit 47. The air supply / water supply nozzle 57 operates the air supply / water supply button 34 to supply air / water to the affected area or to inject cleaning water and air toward the observation window 52. The WJ nozzle 55 injects fluid such as cleaning water and chemicals supplied from a syringe that is detachably attached to the WJ port 36 toward the site to be observed.

  As shown in FIG. 4, a part of the objective optical system 58 is exposed in the observation window 52. The illumination light emitted from the illumination windows 53 and 54 is incident on the objective optical system 58 after reflecting the observation site. The incident subject light enters the prism 59 through the objective optical system 58 and bends inside the prism 59 to form an image on the imaging surface of the image sensor 60. The image pickup device 60 is connected to a circuit board 61, and each signal line 62 of the multicore cable 49 is connected to the circuit board 61.

  An outer layer from the distal end hard portion 23 to the curved portion 24 is formed of an angle rubber 63 having flexibility. A hard distal end side connection ring 64 is provided inside the angle rubber 63. The distal end side connection ring 64 is made of a material having a high thermal conductivity. The distal ends of the operation wires 44 and 46 are fixed to the distal end side connection ring 64 by soldering or the like on the inner periphery. A plurality of connecting pieces 65 are connected to the distal end side connection ring 64, and the connecting range of the plurality of connecting pieces 66 is the curved portion 24. The plurality of connecting pieces 66 are made of a material having high heat conductivity, and are connected alternately by left and right and upper and lower connecting pins 67 and 68 serving as the center of curvature to form a connecting piece row 72 that forms a row in the axial direction. . Inside each connecting piece 65, a pipe-shaped wire guide 69 is integrally provided. Operation wires 44 and 46 are slidably inserted into the wire guide 69. The connecting piece row 72 is bent up and down and left and right by pushing and pulling the two operation wires 43 to 46 for up and down and left and right.

  In addition, a forceps conduit 47 inserted from the flexible portion 25 is disposed inside the bending portion 24. The tip of the forceps conduit 47 is connected to the forceps outlet 56.

  The circuit board 61 mounts the image sensor 60 and also mounts a circuit constituting a driver of the image sensor 60. The circuit board 61, the image sensor 60, and the driver constitute a heating element that serves as a heat source. The circuit board 61 is made of a material having a high thermal conductivity. One end 70 a of a sheet-like heat transfer member 70 is attached to a part of the circuit board 61, for example, the back surface. The other end 70 b of the heat transfer member 70 is fixed to the operation wire 44. In addition, you may fix to the other operation wire 46. FIG. As for fixing, it is desirable to fix the wound tip 70b by bonding or welding with an adhesive 71 having a high thermal conductivity.

  The heat transfer member 70 is preferably made of a material having a high thermal conductivity in order to transfer the heat of the heating element to the operation wire 44. Of course, the inside of the distal end portion 26 is an electric component or machine. Since it is difficult to secure space because there are many parts, mechanical characteristics (for example, flexibility (flexibility)) must be taken into consideration. As a material of the heat transfer member 70 satisfying such conditions, it is desirable to use, for example, a thermal sheet such as a carbon sheet, a thin copper sheet or an aluminum sheet having flexibility. By using the flexible sheet-like heat transfer member 70 having flexibility, it is possible to realize a heat transfer path that passes between the electric machine parts, the wiring, and the like.

  The heat transfer member 70 is preferably made of a material having a high insulating property so as to be brought into contact with the circuit board 61. Further, as the heat transfer member 70, a sealant may be used instead of a flexible sheet-like member having flexibility. By filling the sealant into the distal end portion 26, the circuit board 61 and the operation wire 44 are brought into contact with each other, and the heat of the heating element is transferred to the operation wire 44.

  The operation wires 43 to 46 of this embodiment are made of multi-wall carbon nanotubes (hereinafter referred to as “MWCNT”). Carbon nanotubes have extremely high thermal conductivity. For this reason, the heat of the heating element can be quickly transferred toward the rear in the axial direction (on the operation unit main body side). Single-walled carbon nanotubes may be used.

  As shown in FIG. 5, two pulleys 73 and 74 for up and down and left and right are provided inside the operation unit main body 22, and the pulleys 73 and 74 are arranged so as to be shifted in the rotation axis direction. (See FIG. 6). These pulleys 73 and 74 are made of a material having a high thermal conductivity. The pulley 73 and the bending portion 24 a are connected by operation wires 44 and 46. The operation wires 44 and 46 are a pulley side wire (hereinafter abbreviated as P wire) 75 wound around the pulley 73 and two curved portion side A wires (hereinafter abbreviated as A wire) connected to the curved portion 24a. 46), and the bent portion side B wire (hereinafter referred to as B wire) 44 is divided into three wires, both ends (divided ends) 75a and 75b of the P wire 75, and the A wire 46 and the B wire 44. One end portions (divided ends) 46a and 44a are connected by connecting members 76 and 78, respectively. Specifically, the end portions 46a and 44 of the A wires 46 and 44 are fixed to the connecting members 76 and 78 by welding.

  These connecting members 76 and 78 are made of a material having a high thermal conductivity. The other ends 46b and 44b of the A wire 46 and the B wire 44 are connected to the connecting piece 65 of the bending portion 24a. The pulley 73, the connecting members 76 and 78, the P wire 75, the A wire 46, and the B wire 44 constitute a vertical direction bending drive system. Heat transmitted from the connecting piece 65 of the vertical bending portion 24a is transmitted to the operation wires 43 and 45 via the connecting piece 65 of the left and right bending portion 24b.

  The left and right drive system is also composed of a pulley 74, connecting members 79 and 80, a P wire 81, an A wire 45, and a B wire 43, similarly to the vertical drive system. Both ends (divided ends) 81a and 81b of the P wire 81 are connected to the end portions 45a and 43a of the A wire 45 and the B wire 43 by connecting members 79 and 80, respectively. The other ends 45b and 43b of the A wire 45 and the B wire 43 are connected to the bending portion 24b.

  As shown in FIG. 6, the operation section body 22 is provided with operation knobs 30 and 31 for operating the bending sections 24a and 24b. The operation knobs 30 and 31 are respectively connected to pulleys 74 and 73, respectively. It is connected. The pulleys 74 and 73 are made of a material having a high thermal conductivity. The operation knob 31 is an operation knob for bending the up / down bending portion 24a in the up / down direction, and the operation knob 30 is an operation knob for bending the left / right bending portion 24b in the left / right direction. These operation knobs 30 and 31 are provided to be exposed to the outside of the housing 83 of the operation section main body 22, and the P wires 75 and 81 are pushed along the axial direction of the insertion section 16 in conjunction with each rotation operation. As a result, the bending portions 24a and 24b are bent in the vertical and horizontal directions.

  The four connecting members 76, 78, 79, 80 move in accordance with the pushing / pulling operation of the P wires 75, 81, A and B wires 46, 44, 45, 43. In order to guide this movement, a support member 85 is built in the grip portion 17 as shown in FIG. The support member 85 is made of a material having a high thermal conductivity. Four movement paths 86 to 89 are formed in the support member 85. These moving paths 86 to 89 individually support the connecting members 76, 78, 79, and 80, and prevent them from interfering with each other.

  The support member 85 has a contour shape that narrows toward the insertion portion 16 in accordance with the contour shape of the housing 83 of the operation portion main body 22, and accordingly, the moving paths 86 to 89 also face the distal end portion 26. It has a downward slope. In each of the moving paths 86 to 89, a stopper member 90 that restricts the amount of movement of the connecting members 76, 78, 79, and 80 is provided on the pulleys 73 and 74 side, respectively.

  Since the vertical drive system and the left and right drive system have substantially the same configuration, the vertical drive system will be described below as an example. As shown in FIG. 8, when the operation wires 44 and 46 are pushed and pulled by the rotation of the pulley 73, the connecting members 76 and 78 move, and the relative distance between each connecting member 76 and 78 and the pulley 73 changes. . Assuming that the positions of the connecting members 76 and 78 when the curved portion 24a is straight are the positions (initial positions) shown in FIG. 8A, the pulley 73 is counterclockwise as shown in FIG. 8B. When rotated, the connecting member 76 on the pull side of the P wire 75 moves toward the pulley 73, and conversely, the connecting member 78 on the pushing side moves toward the distal end portion 26. On the other hand, as shown in FIG. 8C, when the pulley 73 rotates clockwise, the connecting member 76 moves toward the distal end portion 26, and the connecting member 78 moves toward the pulley 73.

  The heat transferred from the operation wires 43 to 46 is transferred to the connecting members 76, 78, 79, 80 and the P wires 75, 81, respectively. Since the connecting members 76, 78, 79, and 80 are in contact with the movement paths 86 to 89, the heat transmitted to the connecting members 76, 78, 79, and 80 is radiated to the support member 85. The heat transmitted to the P wires 75 and 81 is radiated to the pulleys 73 and 74. The pulleys 73 and 74 are supported by bearings 91 (see FIG. 6). The bearing 91 is attached to the housing 83. Therefore, the bearing 91 and the housing 83 may be formed of a material having a high thermal conductivity and heat may be radiated from the pulleys 73 and 74 to the housing 83. Further, the close contact coil pipe 51 and the screw tube 37 built in the soft portion 25 are made of a material having a high thermal conductivity, and the heat transmitted to the operation wires 43 to 46 is transmitted via the close contact coil pipe 51. The screw tube 37 may be configured to dissipate heat.

  The operation wires 43 to 46 are MWCNTs made of multi-layered carbon nanotubes, which are hollow carbon fibers having a thickness of several tens of nanometers or less, and have a fiber shape. By the way, carbon fiber is conventionally known. Carbon fiber cannot be made into a concentric cylinder by the manufacturing method, has many structural defects, and the upper limit of strength is determined by the defects. On the other hand, MWCNT can be made into a concentric cylinder, has few defects, and has stable mechanical strength and thermal conductivity regardless of the production method.

The density of carbon nanotubes (hereinafter referred to as “CNT”) is 1.3 to 1.4 g / cm ³ . Conventional wires use steel or stainless steel materials with a density of 7.8 g / cm ³ . The density of CNT is about 1/6 compared with these. Moreover, the tensile strength of CNT is 50 to 70 GPa, which is about 100 times that of iron or stainless steel having a tensile strength of 0.5 Gpa with the same cross-sectional area. Furthermore, the thermal conductivity of CNT is 4000 to 6000 W / m · k, which is 10 times higher than that of copper with a thermal conductivity of 403 W / m · k, and a stainless steel with a thermal conductivity of 16.3 W / m · k. There are more than 200 times. Therefore, the operation wires 43 to 46 and the P wires 75 and 81 made of CNT have the same tensile strength even if the diameter is 1/10 of that of the conventional wires, and therefore may have an extremely small diameter of about 0.05 mm. Even in this case, the thermal conductivity is doubled. Moreover, when the diameter of the CNT is the same as that of a conventional wire, the heat can be passed 200 times, the tensile strength is 100 times stronger, and the durability is improved. Therefore, when the wire is made of CNT so as to cover the characteristics of the conventional wire, a diameter of 0.5 to 0.05 mm is preferable, and when priority is given to heat radiation, a thick wire is inserted. When priority is given to the thinness of 11, it is desirable to select the thickness of the wire according to the purpose, such as a thin wire. In the above embodiment, MWCNT (multi-layer CNT) is used. However, the present invention is not limited to this, and single-wall CNT may be used.

  A plurality of CNTs may be twisted to form a string, which may be used as an operation wire. In this case, it can also be made by synthesizing a plurality of CNTs. Moreover, you may use what twisted several CNT composite materials and made the string. As the CNT composite material, a material in which a single fiber of CNT is blended with plastic, for example, nylon resin or engineering plastic is suitable. By using an operation wire made of fiber with CNT or a composite material mainly composed of CNT, it has higher thermal conductivity and stronger tensile strength than conventional stainless steel and iron wires. Things can be used. For this reason, the diameter of an insertion part and the compactness of an operation part main body can be achieved.

  Moreover, in each said embodiment, the member which contacts the operation wires 43-46 in the axial direction back of the front-end | tip part 26, specifically the front end side connection ring 64, the connection piece 65, the contact | adherence coil pipe 51, the screw tube 37, connection Heat is radiated to the members 76, 78, 79, 80, the support member 85, the pulleys 73, 74, the housing 83, and the like. Examples of materials for these members include stainless steel and ceramic. By using such a material, the heat of the imaging unit can be quickly dissipated.

  In each of the above embodiments, heat is radiated by the connecting piece, the supporting member, the pulley, and the like that come into contact with the operation wire. However, the present invention is not limited to all, and only one of them is used. May be made of a material having a high thermal conductivity to dissipate heat.

  Since CNTs are extremely fine, they may slip with pulleys 73 and 74, which are general groove wheels, and cannot push and pull P wires 75 and 81. In this case, the friction resistance may be increased by covering the P wires 75 and 81 with a rubber tube or a resin pipe. Further, if a known stainless steel wire or the like is used as the P wires 75 and 81, the conventional pulleys 73 and 74 can be used. Moreover, even if it is ultrafine CNT, it can prevent a slip by making the spiral groove connected with one line in a pulley, and winding one operation wire around the spiral groove several times. In any case, there is no problem because heat can be radiated from the connecting members 76, 78, 79, 80 to the support member 85.

  In the above embodiment, the heat generation source is the imaging unit. However, the present invention is not limited to this, and it may be configured to dissipate the heat generated by the illumination unit disposed inside the tip and around the imaging unit. . As the lighting unit, there are a light guide method and an LED method. In the case of the light guide method, light emitted from a lamp built in the light source device is made incident on an illumination lens provided at the tip by a light guide to produce illumination light. In this case, heat generated at the emission end of the light guide may be transferred to the distal end side connection ring by the heat transfer member. In the case of the LED system, a mounting substrate on which a light emitting element that generates heat with light emission is mounted and a tip side connection ring may be connected by a heat transfer member.

DESCRIPTION OF SYMBOLS 10 Endoscope system 24 Bending part 26 Tip part 43-46 Operation wire 61 Imaging element 70 Heat-transfer member

Claims (10)

An operation unit body having an operation knob;
An operation wire pushed and pulled by a pulley that rotates in conjunction with the operation of the operation knob;
A long flexible portion provided in the operation portion main body, a bending portion that is provided on the distal end side of the soft portion with respect to the operation portion main body and curves in conjunction with pushing and pulling of the operation wire, and heat generation An insertion part having a tip part containing the body ,
A heat transfer member disposed within the front Symbol tip connecting said operating wire and the heating element,
A heat dissipating member made of a material having a characteristic of high thermal conductivity, in contact with the operation wire in the axial direction rearward of the insertion portion with respect to the bending portion or the bending portion,
Equipped with a,
The operation wire is made of a carbon nanotube or a composite material mainly composed of carbon nanotubes, and is made in a cross-sectional cylindrical shape having a diameter of 0.5 to 0.05 mm . The endoscope according to claim 1, wherein the operation wire wound around the pulley is covered with a rubber tube or a resin pipe. A connecting member interposed between the operation wires,
The endoscope according to claim 2, wherein the rubber tube or the resin pipe is covered with a pulley-side wire that is wound around the pulley among the operation wires that are divided by the connecting member. The endoscope according to claim 3, wherein the heat dissipation member includes the connecting member. The endoscope according to claim 3 or 4, wherein the heat dissipation member includes a support member that guides the movement of the connecting member. The endoscope according to any one of claims 1 to 5, wherein the heat dissipation member includes the pulley. The endoscope according to claim 1, wherein the heat radiating member includes a connecting piece built in the bending portion. The endoscope according to any one of claims 1 to 7, wherein the heat radiating member includes a coil pipe for guiding the operation wire in the soft portion. The endoscope according to any one of claims 1 to 8, wherein the heat radiating member includes a screw tube provided inside the outer skin of the soft part. An operation unit body having an operation knob;
An operation wire that is made of carbon nanotubes or a composite material mainly composed of carbon nanotubes, and is pushed and pulled by a pulley that rotates in conjunction with the operation of the operation knob;
A long flexible portion provided in the operation portion main body, a bending portion that is provided on the distal end side of the soft portion with respect to the operation portion main body and curves in conjunction with pushing and pulling of the operation wire, and heat generation An insertion part having a tip part containing the body,
A heat transfer member arranged inside the tip and connecting the heating element and the operation wire;
A heat dissipating member made of a material having a characteristic of high thermal conductivity, in contact with the operation wire in the axial direction rearward of the insertion portion with respect to the bending portion or the bending portion,
A rubber tube or a resin pipe covering the operation wire wound around the pulley;
An endoscope characterized by comprising.

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