JP5174330B2 - Endoscope - Google Patents

Description

  The present invention relates to an endoscope in which light emitting means for emitting illumination light is provided in an operation unit.

  Conventionally, as a light source of an endoscope, a light source lamp built in a light source device that is a peripheral device to which the endoscope is connected is well known. When illumination light is supplied from the light source device to the endoscope, the illumination light emitted from the light source lamp is moved from the universal cord of the endoscope by a light guide fiber extending into the endoscope. After being transmitted to the distal end of the insertion part, the test site is irradiated from the distal end of the insertion part.

  In recent years, for the purpose of simplifying the entire endoscope apparatus including an endoscope and peripheral devices, the light source is formed of a light-emitting diode, and the light-emitting diode is connected to the distal end of the insertion portion in the endoscope. An endoscope having a configuration provided therein is well known.

  If a light source composed of a light-emitting diode is provided in the endoscope, a light source device connected to the endoscope becomes unnecessary, so that the endoscope device can be simplified, and the light-emitting diode is a light source lamp. Therefore, it is possible to reduce the power consumption of the endoscope apparatus.

  By the way, since the outer surface of the endoscope after use is usually washed, the endoscope has a watertight structure. That is, the interior of the endoscope is closed by the exterior member except for an opening such as a duct. Further, in order to reduce the weight of the entire endoscope, the exterior member of the endoscope is generally formed of a plastic exterior member.

  However, if the light emitting diode continues to emit light in the sealed space inside the tip of the thin insertion portion covered with the plastic outer member, the plastic outer member has low heat conductivity. There is a problem in that the life of the light emitting diode is reduced due to deterioration due to the heat dissipated in the sealed space having a diameter.

  Therefore, conventionally, considering the heat dissipation efficiency of the plastic exterior member and the life of the light emitting diode, there is a situation in which the light emitting diode has to emit light with a power lower than the rated value. Therefore, there has been a demand for an endoscope that efficiently cools a light emitting diode.

  In view of such circumstances, in Patent Document 1, the light-emitting diode is closely held by the high heat transfer member provided in the sealed space in the distal end of the insertion portion, and a passage through which the fluid flows is provided in the high heat transfer member. By forming a hole to be inserted, the heat of the light emitting diode is transmitted to the fluid flowing through the passage through the high heat transfer member, and is dissipated with the fluid from the distal end of the insertion portion to the outside of the endoscope. The structure which cools is disclosed.

Moreover, in patent document 2, the heat | fever of a light-emitting diode is formed by forming the air supply pipe line which a light emitting diode contacts in the front-end | tip of an insertion part, and the nozzle | cap | die of an air supply pipe | tube with a member with high heat conductivity. The light emitting diode is made to transmit heat to the air supply gas that is slightly lower than the body temperature passing through the inside of the passage and the air supply conduit, and to dissipate heat from the distal end of the insertion portion to the outside of the endoscope together with the air supply gas. The structure which cools is disclosed.
JP 2002-177197 A JP 11-216113 A

  However, in the configurations disclosed in Patent Literature 1 and Patent Literature 2, since the heat of the light emitting diode is radiated together with the fluid toward the distal end side of the insertion portion, that is, into the body cavity, This is not preferable because a fluid slightly higher than the set temperature is supplied to the inspection site.

  Due to such circumstances and the recent aim of further reducing the diameter of the insertion portion, a configuration in which a light emitting diode is provided in the operation portion is also well known. In this case, as shown in Patent Document 1 and Patent Document 2 described above. When the above configuration is applied in the operation unit, the operation unit is inserted with a bending operation wire that bends the bending portion of the insertion unit that is not inserted through the distal end of the insertion unit, an image guide that extends from the imaging device, or the like. Therefore, as a result of securing these insertion spaces, there is a problem that the operation unit becomes large.

  The present invention has been made in view of the above problems, and realizes a configuration capable of efficiently dissipating heat associated with light emission of a light emitting diode outside the space in which the light emitting diode is disposed without increasing the size of the operation unit. It is an object of the present invention to provide an endoscope having a configuration that can be used.

In order to achieve the above object, an endoscope according to an aspect of the present invention includes an elongated insertion portion that is inserted into a subject, an operation portion that is connected to a proximal end side of the insertion portion, the insertion portion, and the insertion portion. A tubular member that extends into the operation portion and that is open at one end of the operation portion and through which the fluid is opened at the other end of the insertion portion, and a light emitting means that emits illumination light provided in the operation portion And a light guide fiber that extends into the insertion portion and transmits the illumination light emitted from the light emitting means to the distal end portion of the insertion portion from the operation portion, and provided in the operation portion, A light emitting means fixing member in which a light emitting means arrangement space in which the light emitting means is arranged and a tubular member insertion hole through which a portion in the operation portion of the tubular member is inserted, and an exterior member of the operation portion in the operation portion The light emitting hand provided fixed to the A heat transfer frame for fixing a fixing member in the operation portion, and a portion of the tubular member in the operation portion is inserted into the tubular member insertion hole at a set position in the operation portion, and the light emitting means is disposed in the light emitting means arrangement space. And a mounting member for attaching the light emitting means fixing member to the heat transfer frame, wherein the light emitting means fixing member is at least between the light emitting means arrangement space and the tubular member insertion hole. and it is formed by the heat transfer member between said thermally conductive frame and said light emitting means arrangement space, the tubular member insertion hole, said light emitting means periphery cut formed in the radial direction toward the center from the stationary member The part which is a notch and faces the outer periphery of the light emitting means fixing member in the notch is covered with the heat transfer frame .

  According to the present invention, an endoscope having a configuration capable of realizing a configuration capable of efficiently dissipating heat associated with light emission of a light emitting diode outside the space in which the light emitting diode is disposed without increasing the size of the operation unit. Can be provided.

  Embodiments of the present invention will be described below with reference to the drawings. In the following embodiments, an endoscope will be described taking as an example a medical endoscope excellent in portability in which a video display device is connected to an operation unit.

  FIG. 1 is a perspective view of an endoscope showing an embodiment of the present invention, FIG. 2 is a partial perspective view of the endoscope of FIG. 1 viewed from the back side of FIG. 1, and FIG. 4 is a partially enlarged plan view showing a state in which the video display device of the endoscope is rotatable, and FIG. 4 is a diagram schematically showing the internal configuration of the endoscope of FIG. 1 mainly with an imaging system and an illumination optical system. .

  As shown in FIG. 1, an endoscope 1 includes an insertion unit 2 that is inserted into a test site in a body cavity that is a subject, an operation unit 3 that is connected to the proximal end side of the insertion unit 2, The video display device 4 connected to the upper end of the operation unit 3 constitutes a main part.

  The insertion portion 2 is formed in an elongated shape having flexibility, and includes a hard distal end portion 5 located on the distal end side, a bending portion 6 provided continuously to the proximal end side of the distal end portion 5, The main part is constituted by the flexible part 7 continuously provided on the base end side of the bending part 6.

  The operation unit 3 includes a gripping unit 8 gripped by the surgeon when the operator grips the endoscope 1 and an operation unit main body 9 provided on the proximal end side of the gripping unit 8. Has been.

  The gripping portion 8 has an outer shape formed in a shape that can be wrapped and gripped by the surgeon, for example, the thumb T (see FIG. 3) of the left hand and other fingers of the left hand, for example, a rod shape. The grasping portion 8 may be formed in a shape that can be grasped by the operator with the right hand.

  In addition, the treatment tool is inserted into and removed from the body cavity by inserting and removing a treatment tool such as forceps into and from a suction conduit 100 (see FIG. 4), which will be described later, extending into the grasping portion 8. A treatment instrument insertion port 10 is provided on the back surface 1 h side of the endoscope 1.

  As shown in FIG. 2, a suction cap 11 is provided on the back surface 1 h side of the endoscope 1 of the operation unit main body 9 that is used when sucking a fluid such as a body fluid or a sputum from the body cavity.

  A suction device can be connected to the suction base 11 via a tube (not shown). The surgeon operates the suction device 11 and operates a suction button 11a (see FIG. 2), which will be described later, so that one end 100t is opened in the operation portion main body 9 and the other end 100s is the distal end portion 5 as shown in FIG. A body fluid, sputum or the like is aspirated from inside the body cavity via a suction conduit 100 (see FIG. 4) that is a tubular member extending into the operation portion 3 and the insertion portion 2 so as to be opened in the distal end surface 5s. be able to.

  Note that a tube may be inserted into the flow channel 100i in the suction conduit 100, and an air supply device for supplying air into the body cavity may be connected to the tube at the suction base 11.

  Further, on the left side of the operation unit main body 9 in FIG. 1, there is provided a vent base 12 that is used for supplying air into the insertion unit 2 and the operation unit 3 when the endoscope 1 is inspected for water leakage. Yes.

  An air supply device can be connected to the vent base 12 via a tube (not shown). The surgeon operates the air supply device and can inspect the water leak of the endoscope 1 by sending air into the endoscope 1 from the vent hole 12 in water.

  In addition, when the endoscope 1 is left under negative pressure, such as sterilization treatment or air transportation, the vent hole 12 is covered with a rubber (not shown) that covers parts of the endoscope 1, for example, the outer periphery of the distal end portion 5. A cap (not shown) for releasing the inside of the endoscope 1 to the atmosphere is detachable so as not to be ruptured by pressure.

  Further, on the front surface 1z side of the endoscope 1 of the operation unit main body 9, a bending operation lever 13 for bending the bending unit 6 in the vertical direction, for example, via a bending operation wire 60 (see FIG. 5). Is provided.

  One end of the bending operation wire 60 is fixed to the distal end of the bending piece (not shown) or the distal end portion 5 in the bending portion 6, and the other end is fixed to a pulley (not shown) disposed in the operation portion 3. And extended in the operation unit 3.

  The bending operation lever 13 is provided at a position close to the grasping portion 8 so that it can be operated by, for example, the thumb T of the left hand of the operator who grasps the grasping portion 8. In addition, the bending operation lever 13 is composed of a finger hooking portion 13a positioned on the front surface 1z side of the endoscope 1 of the operation portion main body 9, and an arm portion 13b connected to the finger hooking portion 13a. It has a letter shape.

  In the bending operation lever 13, the arm portion 13 b is pivotally supported on a rotation shaft 14 that penetrates the operation portion main body 9 in the left-right direction in FIG. Are provided at predetermined positions.

Further, as shown in FIG. 2, the video displayed on the video display device 4 is recorded on the back surface 1h side of the endoscope 1 of the operation unit main body 9 by a recording control circuit 31 (see FIG. 4) described later. An image switch 15 comprising an image recording switch 15a that is turned on when recording on a medium and an image reproduction switch 15b that is turned on when reproducing the recorded image is provided.
Further, the above-described suction button 11 a is provided on the back surface 1 h side of the endoscope 1 of the operation unit main body 9 and in the vicinity of the image switch 15.

  Furthermore, a light emitting diode (hereinafter referred to as an LED) 16 to be described later is disposed in the grasping portion 8 by means to be described later. Further, in the operation portion main body 9, imaging for imaging a region to be examined. An image sensor 17 composed of CCD, CMOS, or the like as means is provided.

  The video display device 4 includes a box-shaped device body 18 having a substantially rectangular parallelepiped shape, and a finger hook extending toward the front surface 1z of the endoscope 1 so as to form a plane from a corner portion of one side of the device body 18. The outer shape is formed by the tilt lever 19 which is a part.

  On the upper surface of the apparatus main body 18, a monitor unit 21 that displays an endoscopic image captured by the image sensor 17, a POWER indicator lamp 23 that is turned on when the power is turned on, and an endoscopic image to be recorded are set as a still image. A still image recording changeover switch 24 that is turned on at the time and a moving image recording changeover switch 25 that is turned on when setting the endoscope image to be recorded to a moving image are provided. The POWER indicator lamp 23, the still image recording changeover switch 24, and the moving image recording changeover switch 25 may be provided on the upper surface of the tilt lever 19.

  Further, the power switch 22 of the endoscope 1 is provided on the surface of the apparatus body 18 on the back surface 1h side of the endoscope 1, and the surface of the apparatus body 18 on the front surface 1z side of the endoscope 1 is provided. Is provided with an openable / closable lid 26 for storing a storage medium such as a battery 34 and a memory card (not shown) in a storage unit (not shown) in the apparatus main body 18 or for detaching from the storage unit. The power switch 22 may also be provided on the upper surface of the tilt lever 19.

  These components arranged in the apparatus main body 18 have a watertight structure. In particular, the lid body 26 that opens and closes is fixed to the housing portion of the apparatus main body 18 by a fixing claw 26a and a buckle lever 26b. It has a reliable watertight structure.

  As shown in FIG. 3, the video display device 4 is connected to the device main body 18 and the operation unit main body 9 by a rotation shaft (not shown) penetrating in the horizontal direction in FIG. Is rotatable between a direction directed toward the upper surface and a direction directed toward the front surface 1z side of the endoscope 1.

  The video display device 4 is rotated by the tilt lever 19 being rotated by, for example, the thumb T of the left hand of the surgeon holding the grip 8. In addition, on the upper surface of the tilt lever 19, a plurality of anti-skids 20 that are convex portions are formed.

  Next, referring to FIG. 4, an internal configuration mainly including the imaging system and the illumination optical system of the endoscope 1 will be described.

  In addition to the monitor unit 21 and the battery 34 described above, the video display device 4 is provided with a power supply control circuit 30, a recording control circuit 31, a display element control circuit 32, and an image sensor control circuit 33 that is a processing circuit. .

  A light guide bundle 35 and an image guide 38 are extended from the insertion portion 2 inside the endoscope 1 to the grip portion 8 of the operation portion 3. The ride guide bundle 35 is configured by covering a light guide fiber (hereinafter simply referred to as a light guide) 35r with a protective tube 35c (both see FIG. 6).

  Further, the above-described suction conduit 100 extends from the distal end portion 5 to the operation portion main body 9, and further, the above-described bending operation wire 60 (FIG. 4) extends from the bending portion 6 to the operation portion main body 9. (Not shown) is extended. Although not shown, the outer periphery of the bending operation wire 60 is covered with a coil, for example.

  Illumination light from, for example, a white LED 16 which is a light emitting means provided in the gripping portion 8 is applied to one end surface of the light guide fiber 35r of the light guide bundle 35 positioned so as to be abutted against the LED 16 in the gripping portion 8. Irradiated.

  After that, the illumination light is transmitted from one end surface of the light guide 35r to the other end surface of the light guide 35r located at the distal end portion 5, and then provided on the distal end side of the other end surface of the light guide 35r in the distal end portion 5. The lens 36 irradiates a predetermined range toward the test site 50 in the body cavity.

  The image of the reflected light from the region to be examined 50 irradiated with the illumination light is incident on the other end of the image guide 38 via the imaging lens 40 and the objective lens 39 provided at the distal end portion 5, and then the image guide. It is transmitted to one end of 38. Thereafter, the image of the reflected light is formed on the image sensor 17 from one end of the image guide 38 via the condenser lens 37 provided in the operation unit main body 9.

  The power supply control circuit 30 supplies the power supplied from the battery 34 to each circuit for the LED 16, the image sensor 17, the monitor unit 21, the recording control circuit 31, the display element control circuit 32, and the image sensor control circuit 33. Outputs the corresponding driving power.

  The power supply control circuit 30 includes the power switch 22 described above, and is turned on / off by the power switch 22. The battery 34 is composed of a secondary battery that can be repeatedly charged and used.

  An image of the test site 50 imaged by the image sensor 17 is output from the image sensor 17 to the image sensor control circuit 33. The image sensor control circuit 33 converts the image of the test site 50 imaged by the image sensor 17 into a signal and outputs the signal to the recording control circuit 31 and the display element control circuit 32.

  A recording medium such as an XD picture card is detachably attached to the recording control circuit 31. The recording control circuit 31 includes an image switch 15 (see FIG. 2) provided in the operation unit main body 9 and a still image recording change switch 24 and a moving image recording change switch 25 provided in the video display device 4 (both are both). An input signal from (see FIG. 1) is supplied.

  In response to the input signals from these various switches, the recording control circuit 31 performs control such as recording, reproducing, and stopping the endoscope image signal as a still image or a moving image. That is, the recording control circuit 31 stores the image of the test site 50 converted into a signal by the image sensor control circuit 33 in a recording medium, and uses the stored signal as an instruction signal from the image reproduction switch 15b such as reproduction and stillness. Is output to the display element control circuit 32 in response to the input.

  The display element control circuit 32 visualizes the signal from the recording control circuit 31 or the image sensor control circuit 33 and causes the monitor unit 21 to display an endoscopic image. In addition, the recording control circuit 31 sends a power supply instruction signal to the LED 16, the image sensor 17, and the image sensor control circuit 33 in response to signal input from the various switches 15, 24, and 25 to the power supply control circuit 30. Supply.

  When the power switch 22 is turned on, the endoscope 1 configured in this way is supplied with electric power from the power supply control circuit 30 of the video display device 4 and is activated in the image reproduction mode. An image recorded in the recording control circuit 31 is displayed. In this state, power is not supplied from the power supply control circuit 30 to the LED 16 and the image sensor 17.

  Thereafter, for example, when the still image recording changeover switch 24 is turned on by the surgeon to enter a still image recording standby state, power is also supplied from the power supply control circuit 30 to the LED 16 and the image sensor 17, and the image being observed becomes an image sensor. 17, the image sensor control circuit 33, the display element control circuit 32, and the monitor unit 21 are transmitted in this order and displayed on the monitor unit 21 in real time.

  When recording a still image in this state, when the image recording switch 15a is turned on by an operator, an image signal is taken into the recording control circuit 31 from the image sensor control circuit 33, and is recorded on the recording medium of the recording control circuit 31. A still image is recorded in a certain internal memory. In addition, after recording, the image under observation is automatically displayed on the monitor unit 21 again.

  Thereafter, when the image reproduction switch 15 b is turned on by the surgeon, an image signal is output from the recording control circuit 31 to the display element control circuit 32, and the recorded still image is displayed on the monitor unit 21. Thereafter, when the image reproduction switch 15b is turned off by the operator, the image being observed is displayed on the monitor unit 21 instead of displaying a still image.

  In this state, when the operator turns on the moving image recording changeover switch 25, the moving image recording standby state is set. In this case, the image being observed is transferred from the image sensor 17 to the image sensor control circuit 33, the display element. The information is transmitted in the order of the control circuit 32 and the monitor unit 21 and displayed on the monitor unit 21 in real time.

  When recording a moving image in this state, when the operator turns on the image recording switch 15a, the moving image is recorded in the internal memory of the recording control circuit 31 as described above.

  During moving image recording, either the image sensor control circuit 33 or the recording control circuit 31 outputs an image signal to the display element control circuit 32 in real time, and the observation image is displayed on the monitor unit 21 in real time.

  Thereafter, when the image recording switch 15a is turned off by the surgeon, the recording is stopped, and instead of displaying a moving image, the image being observed is displayed on the monitor unit 21. Subsequently, in the case of performing the moving image reproduction, when the image reproduction switch 15b is turned on by the operator, the same moving image reproduction control as the still image reproduction is performed. When the moving image reproduction ends, the same control as that for the above-described still image reproduction ends is performed, and the above-described startup state is restored.

  Next, the structure which arrange | positions LED16 in the operation part 3 is demonstrated using FIG. 5, FIG. 5 is a partially enlarged cross-sectional view schematically showing an internal configuration of the operation unit of the endoscope of FIG. 1, and FIG. 6 is an end view taken along the line VI-VI in FIG.

  As shown in FIGS. 5 and 6, the interior of the gripping portion 8 of the operation portion 3 that is watertightly closed by the exterior member 3 g is along the front 1 z side and the back 1 h side of the endoscope 1 of the exterior member 3 g. The metal frame 80, which is a plate-like heat transfer frame formed in a semicircular shape, extends in the insertion axis direction J so as to face each other. Each metal frame 80 is fixed by screws 95 to each interposed plate 81 fixed to the inner surface of the exterior member 3g.

  Further, the suction pipe 100, the image guide 38, the bending operation wire 60, and the light guide bundle 35 are extended in the space between the opposing metal frames 80 and supplied from the battery 34. A lead wire 30s extending from the power supply control circuit 30 to the LED 16 for transmitting electric power to the LED 16 is also extended.

  Further, the light emitting means fixing member 70 is fixed in the space between the opposing metal frames 80 by screws 90 which are attachment members. That is, the light emitting means fixing member 70 is fixed in the grip portion 8.

  The light emitting means fixing member is conventionally used as a member to which the bending operation wire 60 is fixed by abutting the above-described coil that covers the outer periphery of the bending operation wire 60. The light emitting means fixing member 70 of the present embodiment is formed larger than the conventionally used light emitting means fixing member.

  As shown in FIGS. 5 and 6, the light emitting means fixing member 70 is formed of, for example, a solid substantially columnar member, and is formed of a heat transfer member such as aluminum or brass. In addition, through holes 70 a to 70 e are formed in the light emitting means fixing member 70 along the insertion axis direction J, respectively.

  The through hole 70a constitutes the tubular member insertion hole of the present invention. As shown in FIG. 6, in the light emitting means fixing member 70, for example, it moves eccentrically from the center to the front surface 1z side of the endoscope 1. It is formed at the position.

  In the through hole 70 a, the portion of the suction conduit 100 extending into the grip 8 is at least a part of the outer periphery of the tube 144 covered by the outer periphery of the suction conduit 100 (the entire periphery in FIG. 6). Is inserted in close contact with the inner periphery of the through hole 70a.

  The through hole 70b constitutes the light emitting means arrangement space of the present invention, and has a large diameter hole in which the LED base 76 described later is disposed, and a small diameter hole in which the light guide bundle 35 and the lead wire 30s are inserted. To form a stepped hole.

  In addition, the through hole 70b is formed at a position in the light emitting means fixing member 70 that is eccentrically moved from the center to the back surface 1h side of the endoscope 1, for example. Further, as shown in FIG. 6, the through hole 70b is formed at a position where the center of each of the holes 70b and 70a is coaxial with the through hole 70a on a line connecting the front surface 1z side and the back surface 1h side. It does not matter.

  The end portion side of the lead wire 30s extending from the power supply control circuit 30 is inserted into the small diameter hole of the through hole 70b, and is disposed so as to abut one end surface side of the light guide bundle 35 or the one end surface. LED 16 is inserted.

  Further, a metal LED base 76 to which the LED 16 is fixed is inserted into the large-diameter hole of the through hole 70 b so that the LED 16 abuts against one end surface of the light guide bundle 35. The LED base 76 is provided with a substrate to which the end of the lead wire 30s is connected.

  The LED base 76 is fixed so as to be in close contact with the inner periphery of the large-diameter hole of the through hole 70b. As a result, the LED 16 is fixed in the grip portion 8 that is the set position.

  In the light emitting means fixing member 70, the through hole 70c is formed, for example, at a position between the through hole 70a and the metal frame 80 adjacent to the through hole 70a. The image guide 38 is inserted into the through hole 70c. Has been.

  The through holes 70d and 70e are formed in the light emitting means fixing member 70 at positions symmetrical with respect to an axis W orthogonal to the direction connecting the front surface 1z side and the back surface 1h side of the endoscope 1, for example. The coils of the bending operation wire 60 are brought into contact with the through holes 70d and 70e, and the bending operation wire 60 is inserted therethrough.

  Next, the operation of the embodiment configured as described above will be described. In addition, the effect | action shown below demonstrates the effect | action of the thermal radiation method in the operation part 3 of LED16.

  First, when the power switch 22 of the endoscope 1 is turned on and then the still image recording changeover switch 24 or the moving image recording changeover switch 25 is turned on, power is supplied to the LED 16 from the power supply control circuit 30 of the video display device 4. Is done. As a result, the LED 16 starts to emit light, and the illumination light emitted by the LED 16 is irradiated to a predetermined range by the illumination lens 36 toward the test site 50 in the body cavity via the ride guide bundle 35. .

  At this time, heat N is radiated from the LED 16 as the LED 16 emits light in the through hole 70 b of the light emitting means fixing member 70 fixed between the two metal frames 80. The heat N of the LED 16 radiated into the through hole 70b is obtained by forming the LED base 76 from a metal member and the light emitting means fixing member 70 from a heat transfer member. Heat is transferred through the LED base 76 and the light-emitting means fixing member 70 to the suction conduit 100 in which at least a part of the outer periphery of the tube 144 is in close contact with 70a (see FIG. 5).

  Thereafter, the suction button 11a is turned on, and the suction device connected to the suction base 11 is driven, so that fluid such as bodily fluid or sputum that has been sucked from inside the body cavity flows into the inside 100i of the suction pipe 100. Therefore, the heat N radiated from the LED 16 is absorbed by the fluid flowing through the inside 100 i of the suction conduit 100 and is discharged from the suction base 11 together with the fluid to the outside of the endoscope 1.

  When no fluid is flowing into the inside 100i of the suction pipe 100, the heat N is transferred again from the suction pipe 100 to the light emitting means fixing member 70, and then the heat N is generated in the light emitting means fixing member 70. Heat is transferred to the metal frame 80 in the vicinity of the suction pipe line 100 through heat conduction, and heat is radiated from the metal frame 80 into a space that is watertightly closed by the exterior member 3g of the grip portion 8 of the operation unit 3. .

  At this time, the heat N is dissipated into the space between the metal frame 80 and the exterior member 3 g in the operation unit 3, but the LED 16 is in the through hole 70 b in the light emitting means fixing member 70 between the metal frames 80. Since the LED 16 is disposed, the LED 16 is not heated by the radiated heat N.

  Further, the heat N of the LED 16 radiated into the through hole 70b is a metal adjacent to the through hole 70b because the LED base 76 is formed of a metal member and the light emitting means fixing member 70 is formed of a heat transfer member. Heat is directly transferred to the frame 80 via the LED base 76 and the light emitting means fixing member 70 (see FIG. 5).

  Thereafter, the heat N transferred to the metal frame is dissipated from the metal frame 80 into a space that is watertightly closed by the exterior member 3g of the grip portion 8 of the operation unit 3. At this time as well, the heat N is radiated to the space between the metal frame 80 and the exterior member 3g in the operation unit 3, but for the reason described above, the LED 16 may be heated by the radiated heat N. Absent.

  As described above, in the present embodiment, when the LED 16 is disposed in a space that is watertightly covered with the exterior member 3g in the grip portion 8 of the operation unit 3, the two metals fixed to the exterior member 3g. A light emitting means fixing member 70 formed of a heat transfer member is fixed between the frames 80. Through holes 70a and 70b are formed in the light emitting means fixing member 70, and the LEDs 16 are disposed in the through holes 70b. It is shown that the suction line 100 is inserted into 70a.

  According to this, when the LED 16 generates heat due to light emission, the heat N is transferred to the suction conduit 100 and the metal frame 80 through heat conduction in the light emitting means fixing member 70, and the suction conduit 100. Since the heat is radiated through the metal frame 80 and the inside of the through hole 70b is not heated, the heat of the LED 16 can be efficiently radiated outside the space where the LED 16 is disposed. From this, deterioration of LED16 can be prevented and the lifetime reduction of LED16 can be prevented.

  Further, since the light emitting means fixing member 70 is formed with a through hole 70c through which the image guide 38 is inserted and through holes 70d and 70e through which the bending operation wire 60 is inserted, the image guide 38 and the bending operation wire are formed. It is not necessary to separately secure a space through which 60 is inserted.

  That is, the image guide 38 and the bending operation wire 60 are appropriately disposed in the operation unit 3 by the light emitting means fixing member 70. For this reason, even if the image guide 38 and the bending operation wire 60 are disposed in the grip 8 of the operation unit 3, the operation unit 3 is not enlarged.

  From the above, a configuration that can efficiently dissipate the heat N accompanying the light emission of the LED 16 outside the space in which the LED 16 is disposed without providing a special cooling means is simple without increasing the size of the operation unit 3. The endoscope 1 that can be realized by the configuration can be provided.

  Further, in the present embodiment, since the LED 16 is disposed in the operation portion 3, the shape of the distal end portion 5 of the insertion portion 2 is not limited to a circular shape or a square shape, but various shapes. Can be formed.

  A modification will be described below. In the present embodiment, it is shown that the entire light emitting means fixing member 70 is formed of a heat transfer member made of aluminum, brass or the like.

  Not limited to this, at least between the through hole 70a through which the suction conduit 100 is inserted in the light emitting means fixing member 70 and the through hole 70b in which the LED 16 is disposed, or only between the through hole 70b and the metal frame 80 is transmitted. If formed from a heat member, the heat N from the LED 16 is reliably transferred to the metal frame 80 or the suction conduit 100 even if the entire light emitting means fixing member 70 is not formed from a heat transfer member.

  Therefore, if the portion other than the portion formed by the heat transfer member of the light emitting means fixing member 70 is formed of resin or the like, the same effect as the present embodiment can be obtained while making the endoscope 1 lighter than the present embodiment. Can be obtained.

  Of course, if the light emitting means fixing member 70 is formed of a heat transfer member, the forming member is not limited to aluminum or brass.

  Hereinafter, another modification will be described with reference to FIG. FIG. 7 is an end view schematically showing a configuration of a modified example inside the operation unit of the endoscope.

  As shown in FIG. 7, in the light emitting means fixing member 70, instead of the above-described through holes 70a and 70c, a notch 170 extending from the outer periphery of the light emitting means fixing member 70 toward the center along the radial direction is formed on the insertion axis J. It may be formed so as to penetrate the light emitting means fixing member 70 along. In this case, the suction conduit 100 and the image guide 38 are inserted through the notch 170. That is, in this case, the notch 170 forms a tubular member insertion hole in the present invention.

  Even in this case, at least a part of the tube 144 of the suction conduit 100 is always in contact with the notch 170. In this case, the suction conduit 100 and the image guide 38 may move in the radial direction of the light emitting means fixing member 70 in the notch 170, but the metal frame 80 faces the outer periphery of the notch 170. Since the portion is covered, the suction conduit 100 and the image guide 38 do not jump out of the light emitting means fixing member 70.

  It should be noted that the suction pipe 100 and the image guide 38 are fixed to the fixing member 110 (see FIG. 5; FIG. 5 shows the suction pipe line) at two points of the light emitting means fixing member 70 in the insertion axis direction J. Since only the fixing member for fixing the rear end side of 100 is fixed), the notch 170 does not move so much.

  Even if the suction conduit 100 moves in the radial direction in the notch 170, the tube 144 is always in contact with the notch 170, so that heat transfer is performed via the light emitting means fixing member 70. The generated heat N is reliably transferred to the suction pipe line 100 through heat conduction in the light emitting means fixing member 70.

  Thus, if the notch 170 is formed in the light emitting means fixing member 70 and the suction pipe 100 is inserted into the notch 170, the suction is performed in the case where no fluid flows into the inside 100i of the suction pipe 100. When heat N is radiated from the metal frame 80 through the heat conduction of the light emitting means fixing member 70 from the pipe line 100, the suction pipe line 100 is inserted into the through hole 70a as in the above-described embodiment. Compared to the case, the surface area when heat is radiated from the suction conduit 100 is not only the outer surface of the suction conduit 100 but also the inner peripheral surface of the notch 170 and the outer surface of the metal frame 80 with which the notch 170 contacts. Minutes get bigger. Therefore, the heat N can be radiated more efficiently from the light emitting means fixing member 70 than in the present embodiment.

  Further, another modification will be described below with reference to FIG. FIG. 8 is a cross-sectional view schematically showing a configuration of another modified example inside the operation unit of the endoscope.

  In the present embodiment, it is shown that the light emitting means fixing member 70 is fixed to the metal frame 80. Not only this but as shown in FIG. 8, the light emission means fixing member 70 may be integrally formed with the metal frame as the light emission means fixing member 270.

  According to this, in the endoscope 1, while reducing the number of parts, the LED 16 is disposed in the through-hole 70 b in the gripping portion 8 of the operation portion 3 while eliminating the influence of heat radiation from the LED 16. be able to.

  Hereinafter, still another modification will be described with reference to FIGS. 9 and 10. FIG. 9 is a partial cross-sectional view showing a modification in which a bending operation wire or a groove through which an image guide is inserted is formed in the light emitting means fixing member, and FIG. 10 shows a state in which the bending operation wire is inserted into the groove in FIG. It is a fragmentary sectional view shown.

  In the present embodiment, the light emitting means fixing member 70 is formed with a through hole 70c through which the image guide 38 is inserted, and a coil of the bending operation wire 60 is abutted and the bending operation wire 60 is inserted. It was shown that through holes 70e and 70d were formed.

  Not limited to this, as shown in FIG. 9, the groove 370 into which the image guide 38 or the bending operation wire 60 with which the outer periphery of the bending operation wire 60 is abutted is inserted into the outer periphery of the light emitting means fixing member 70. Each of the light emitting means fixing members 70 may be formed along J.

  In this case, as shown in FIG. 10, the bending operation wire 60 is inserted into the groove 370 in a state where the outer peripheral coil is abutted with the metal frame 80. Although not shown, the image guide 38 is inserted into a groove 370 different from the groove 370 through which the bending operation wire 60 is inserted between the image guide 38 and the metal frame 80.

  Thus, if the groove 370 is formed in the light emitting means fixing member 70 instead of the through holes 70c to 70e, the light emitting means fixing member 70 can be formed smaller than this embodiment. A configuration that can efficiently dissipate the heat N accompanying the light emission of the LED 16 to the outside of the space where the LED 16 is disposed can be realized by downsizing the operation unit 3 as compared with the present embodiment.

  Further, in the present embodiment, the tubular member is illustrated by taking the suction conduit 100 as an example. However, the tubular member is not limited to this, and the conduit in which a fluid such as a forward water supply conduit flows in the endoscope 1 is not limited thereto. When the is extended, the heat N radiated from the LED 16 may be transferred to the pipe. In other words, as long as the fluid flows, the heat N radiated from the LED 16 may be transferred to any conduit.

  In the present embodiment, the imaging element 17 is described as being provided in the operation unit main body 9, but is not limited thereto, and may be provided in the distal end portion 5 of the insertion unit 2. . At this time, the image of the test site 50 imaged by the image sensor 17 is stored in the video display device 4 via an imaging cable (not shown) extending from the image sensor 17 into the insertion unit 2 and the operation unit 3. Is output to the image sensor control circuit 33, which is a processing circuit.

  Therefore, in this case, the light emitting means fixing member 70 may be formed with a through hole through which the imaging cable is inserted or the groove described above, or the imaging cable may be inserted into the through hole 70c.

  Further, in the present embodiment, the endoscope 1 is shown by taking a medical endoscope as an example. However, even when applied to an industrial endoscope, the same effect as the present embodiment is obtained. Can be obtained. Needless to say, if the LED is an endoscope disposed in the operation unit, the present invention can be applied to an endoscope other than the endoscope in which the video display device is disposed at the upper end of the operation unit. .

The perspective view of the endoscope which shows embodiment of this invention. The partial perspective view which looked at the endoscope of FIG. 1 from the back side of FIG. The partial enlarged plan view which shows the state which the image display apparatus of the endoscope of FIG. 1 can rotate freely. FIG. 2 is a diagram schematically illustrating an internal configuration of the endoscope of FIG. 1 mainly including an imaging system and an illumination optical system. The partial expanded sectional view which shows schematically the structure inside the operation part of the endoscope of FIG. FIG. 6 is an end view taken along line VI-VI in FIG. 5. The end elevation which shows roughly the structure of the modified example inside the operation part of an endoscope. Sectional drawing which shows schematically the structure of another modification inside the operation part of an endoscope. The fragmentary sectional view which shows the modification by which the groove | channel by which a bending operation wire or an image guide was penetrated was formed in the light emission means fixing member. FIG. 10 is a partial cross-sectional view showing a state where a bending operation wire is inserted into the groove of FIG. 9.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Endoscope 2 ... Insertion part 3 ... Operation part 3g ... Exterior member 5 ... Tip part 6 ... Bending part 16 ... LED
DESCRIPTION OF SYMBOLS 17 ... Imaging device 35 ... Light guide bundle 35r ... Light guide fiber 38 ... Image guide 60 ... Bending operation wire 70 ... Light emission means fixing member 70a ... Through-hole 70b ... Through-hole 70c ... Through-hole 70d ... Through-hole 70e ... Through-hole 80 ... Metal frame 90 ... Screw 100 ... Suction line 100s ... The other end of the suction line 100t ... One end of the suction line 170 ... Notch 370 ... Groove

Claims (6)

An elongated insertion part to be inserted into the subject;
An operation unit continuously provided on the proximal end side of the insertion unit;
A tubular member that extends into the insertion portion and the operation portion, passes through a fluid that has one end opened in the operation portion and the other end opened in the insertion portion;
A light emitting means for emitting illumination light provided in the operation section;
A light guide fiber that extends into the insertion portion and transmits the illumination light emitted from the light emitting means from the operation portion to the distal end portion of the insertion portion;
A light-emitting means fixing member provided in the operation section, in which a light-emitting means arrangement space in which the light-emitting means is arranged and a tubular member insertion hole through which a portion of the tubular member in the operation section is inserted;
A heat transfer frame for fixing the light emitting means fixing member in the operation portion, which is provided in the operation portion and fixed to the exterior member of the operation portion;
In a state where the tubular member insertion hole is inserted through the tubular member insertion hole and the light emitting unit is disposed in the light emitting unit disposition space, the light emitting unit fixing member is disposed at the set position in the operation unit. A mounting member attached to the heat transfer frame;
Comprising
The light emitting means fixing member is formed by a heat transfer member at least between the light emitting means and said thermally conductive frame and between said light emitting means arrangement space between the configuration space and said tubular member insertion hole,
The tubular member insertion hole is a notch formed radially from the outer periphery of the light emitting means fixing member toward the center,
The endoscope is characterized in that a portion of the notch facing the outer periphery of the light emitting means fixing member is covered with the heat transfer frame .   The endoscope according to claim 1, wherein the tubular member insertion hole is a through hole, and the tubular member is inserted into the through hole with at least a part of an outer periphery thereof being in close contact with each other. . It said tubular member is an endoscope according to claim 1 or 2, wherein the opening of said operating portion of said one end, characterized in that a freely suction conduit connected to a suction device. A bending portion that bends the distal end portion is connected to the proximal end side of the distal end portion in the insertion portion, and a bending operation wire that is used when the bending portion is bent in the insertion portion and the operation portion. Is extended,
The light emitting means fixing member is formed with a hole through which the bending operation wire is inserted or a groove which is opened on an outer periphery of the light emitting means fixing member and is covered with the heat transfer frame. The endoscope according to any one of Items 1 to 3 . An imaging means for imaging a test site of the subject is provided in the operation unit, and an image guide for allowing the image sensor to receive an image of the test site in the insertion unit and the operation unit. Extended,
The light emitting means fixing member is formed with a hole through which the image guide is inserted or a groove which is opened on an outer periphery of the light emitting means fixing member and is covered with the heat transfer frame. The endoscope according to any one of 1 to 4 . An imaging unit that images the test site of the subject is provided at the distal end of the insertion unit, and an image of the test site is processed from the imaging unit in the insertion unit and the operation unit. The imaging cable that transmits to the circuit is extended,
The light emitting means fixing member is formed with a hole through which the imaging cable is inserted or a groove which is opened in the outer periphery of the light emitting means fixing member and is covered with the heat transfer frame. Item 5. The endoscope according to any one of Items 1 to 4 .

Images