JP5371677B2 - Imaging device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an imaging apparatus that reduces the diameter of the leading end of an insertion part or the length of a hard part by moving a movable-lens frame into contact with a positioning part, thereby immediately switching between an enlarged viewing condition and a regular viewing condition. <P>SOLUTION: The imaging apparatus 30 includes: a movable-lens frame 42 having a movable lens 45, able to advance and retract in the direction of an optical axis, and restricted to a forward movement position and a backward movement position by position restricting portions 43a and 43b; a first rear spring 62 abutting on the basal end face of the movable-lens frame 42 and having a holding force with which the movable-lens frame 42 is constantly held in the forward movement position; a movable-lens frame moving mechanism 50 for moving the movable-lens frame 42 by the power of a motor 70 or the like; and a nut 54 for switching between the state in which power from the movable-lens moving mechanism 50 advances or retracts the movable-lens frame 42 and the state in which when the advancing or retracting movable-lens frame 42 reaches the forward movement position or the backward movement position, impact from the movable-lens frame 42 is prevented from being directly transmitted to the movable-lens frame moving mechanism 50. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to an imaging apparatus including a moving lens frame that varies optical characteristics of an objective optical system disposed in, for example, an endoscope.

  Electronic endoscopes are widely used for in-vivo observation, treatment, etc., or inspection, repair, etc. in industrial plant equipment. In endoscopic observation, a device capable of changing optical characteristics such as a depth of focus, an imaging magnification, and a viewing angle with respect to an observation target is desired depending on an observation site or an observation purpose.

  In recent years, there has been known an imaging apparatus in which one or a plurality of optical lenses included in the imaging apparatus is configured to be movable in the optical axis direction, and optical characteristics can be adjusted and changed. ing.

  An endoscope capable of normal observation and magnified observation includes a moving mechanism that moves a moving lens frame having an optical lens in the optical axis direction in an imaging device built in the insertion portion. For example, the moving lens frame is in a normal observation state when it is moved to the distal end side of the endoscope insertion portion, and is in an enlarged observation state as it is moved to the proximal end side. When the movable lens frame is moved to the most proximal side, the maximum observation state is obtained.

  That is, the movable lens is configured to obtain a predetermined normal observation state by being disposed at a predetermined position on the distal end side, and to obtain a maximum observation state by being disposed at a predetermined position on the proximal end side.

  In the endoscope imaging apparatus, the moving amount of the moving lens is set to a very small amount, for example, in a range of 0.3 mm to 1.0 mm.

  Further, as the moving mechanism, a mechanism for moving the wire connected to the moving lens frame forward or backward by an operation lever or a drive motor provided in the operation unit, or an urging spring and a shape memory alloy are provided in the endoscope insertion unit, A mechanism for moving the moving lens frame back and forth by energizing and stopping energization is well known.

  According to these moving mechanisms, the moving lens is disposed at a predetermined position on the distal end side by contacting a part of the moving lens frame or a member integral with the moving lens frame with the distal positioning member, and positioning on the proximal end side. By contacting the member, it is arranged at a predetermined position on the proximal end side.

  Further, Patent Document 1 shows an endoscope apparatus in which position selection of a movable lens (corresponding to the above-described moving lens) is performed in a multistage manner with a relatively simple configuration and high accuracy is ensured. In this endoscope apparatus, the movable lens portion (corresponding to the aforementioned moving lens frame) can be held at the intermediate position of the movable stroke in addition to the front end side position and the rear end side position of the movable stroke. ing. In this endoscope apparatus, a magnet is provided in a case body provided in an operation unit main body for moving a wire, and a plurality of magnets having a polarity opposite to that of the magnet are provided in an accommodation recess to move a movable lens unit. It is the structure hold | maintained at the front end side position of a stroke, an intermediate position, and a rear end side position.

JP 2000-22215 A

  However, in the moving mechanism described above, for example, when the moving lens frame that is moved along with the movement of the wire by the drive motor is configured to stop (collision) against the positioning member, the moving lens frame and the positioning member There is a possibility that the imaging apparatus may malfunction due to the impact force when the two collide. Further, when the moving lens frame hits the positioning member, the movement of the moving lens frame is suddenly stopped, so that a large load is applied to the wire, and the wire may be deteriorated. In addition, when the moving lens frame is suddenly stopped, the driving motor in the driving state or the gear train that transmits the driving force of the motor to the wire is also suddenly stopped, so that the driving motor and gears are heavily loaded and damaged. There was a risk of doing so.

  In order to solve these problems, if the wire's forward / backward speed by the drive motor is reduced to reduce the impact force at the time of collision, the wire's forward / backward speed becomes slow and the observation state cannot be switched quickly. Arise.

  On the other hand, when a sensor such as an optical sensor or a piezoelectric sensor is provided in the imaging device for the purpose of solving the problem that the moving lens frame collides with the positioning member, the moving mechanism becomes complicated and large, and the diameter of the distal end of the insertion portion is large. Or a problem that the hard length increases.

  Also in Patent Document 1, the movable lens portion is held at the rear end side position of the movable stroke when it comes into contact with the rear end surface of the lumen portion of the fixed lens barrel, and the distal end portion of the operation wire is fixed to the fixed lens barrel. It is the structure which is hold | maintained in the front-end side position of a movable stroke when it contact | abuts to a stopper part. Accordingly, the above-described trouble due to the impact occurs. In addition, in the configuration in which the movable lens unit is held at the front end side position, the intermediate position, and the rear end side position of the movable stroke by the magnet's attractive force, the movable lens unit is moved from one end side to the other end side, and the observation state When switching the observation state from the maximum observation state to the normal observation state, it is difficult to smoothly perform the operation of releasing the adsorption state between the magnets and the operation of allowing the magnet to pass without being attracted at the intermediate position, and switching the observation state quickly. It was difficult.

  Note that when an electrostatic actuator or a linear cam is used as the moving mechanism, the mechanism for moving the moving lens is enlarged, leading to an increase in the diameter of the distal end of the insertion portion and an increase in the hard length.

  The present invention has been made in view of the above circumstances, and it is possible to quickly switch between the maximum observation state and the normal observation state by moving the movable lens frame and bringing it into contact with the positioning portion, and the insertion portion distal end portion. It is an object of the present invention to provide an imaging device that can reduce the diameter of the lens or shorten the length of the hard part.

An imaging device according to one embodiment of the present invention includes an optical lens, is movable in and out in the optical axis direction, is defined by a position restricting unit at a forward position and a backward position, and a base end surface of the movable lens frame. A forward position holding member that is disposed in contact and has a holding force to always hold the moving lens frame in the forward position; a moving lens frame moving mechanism that moves the moving lens frame by manual power or actuator power; When the power is transmitted from the moving lens frame moving mechanism unit to the moving lens frame to move the moving lens frame forward or backward, or when the moving lens frame moving forward or backward reaches the forward position or the backward position, the moving lens comprising a transmitting state switching unit for switching from the frame in a state in which the impact force is not transmitted to the movable lens frame moving mechanism, wherein the movable lens frame moving mechanism A transmission member for transmitting a rotational force, a shaft member having a male screw portion formed on an outer peripheral surface, a connecting member for connecting the shaft member and the transmission member so as to transmit power, and a male screw for the shaft member A nut which is a transmission state switching portion which is formed on the front end side of the moving lens frame and is capable of moving forward and backward with respect to the shaft member. A first impact mitigating member that is disposed in contact with the surface, has a holding force to constantly press the nut against the moving lens frame, and mitigates an impact when the moving lens frame hits a forward position of the position restricting portion; And the elastic constant of the forward position holding member that abuts before the moving lens frame hits the retracted position of the position restricting portion and reduces the impact when the moving lens frame hits the retracted position. A second shock absorbing member having a large elastic constant, in the configuration, the nut and the first shock absorbing member also serves as the transmission state switching unit.

  According to the present invention, it is possible to quickly switch between the maximum observation state and the normal observation state by moving the moving lens frame and bringing it into contact with the positioning portion, and reducing the diameter of the distal end portion of the insertion portion or the length of the hard portion. An imaging device that can be shortened can be realized.

1 to 7 relate to a first embodiment of the present invention, and FIG. 1 illustrates an electronic endoscope system. The figure explaining the imaging device which equips the lens unit arrange | positioned at the front-end | tip part of an electronic endoscope with a moving mechanism part. FIG. 3 is a cross-sectional view taken along arrows Y3 and Y3 in FIG. 2, and is a front view illustrating a moving lens frame that is moved by a moving mechanism unit disposed at a tip portion It is a figure explaining the effect | action of a moving mechanism part, and the figure explaining the state which the drive motor started rotation It is a figure explaining the effect | action of a moving mechanism part, and is a figure explaining the state which a nut contact | abuts to a moving lens frame and starts a movement. It is a figure explaining the effect | action of a moving mechanism part, and is a figure explaining the state which the 1st back spring was compressed with the moving moving lens frame, and the moving lens frame contacted the 2nd back spring. It is a figure explaining the effect | action of a moving mechanism part, and is a figure explaining the state in which the moving lens frame is contact | abutting to the backward position control part The figure explaining the lens unit concerning the modification of 1st Embodiment and having arrange | positioned the 1st back spring and the 2nd back spring in series. It is a figure explaining the effect | action of the moving mechanism part of a modification, and the figure explaining the state which the drive motor started rotation It is a figure explaining the effect | action of the moving mechanism part of a modification, and a figure explaining the state which a nut contact | abuts to a moving lens frame and starts a movement. It is a figure explaining the effect | action of the moving mechanism part of a modification, The 1st back spring is compressed by the moving moving lens frame, The state which the spring force of a 2nd back spring is acting on a moving lens frame is shown. Illustration to explain It is a figure explaining the effect | action of the moving mechanism part of a modification, and the figure explaining the state which the moving lens frame is contact | abutting to the retreat position control part The figure explaining the buffer spring which constituted the 1st back spring and the 2nd back spring integrally. It is a figure explaining the effect | action of the moving mechanism part of 2nd Embodiment, and the figure explaining the state which the drive motor started rotation It is a figure explaining the effect | action of the moving mechanism part of 2nd Embodiment, The spring force of a front spring and the spring force of a rear spring balance, and the state which a movable lens frame can move with the movement of a nut with a convex part is shown. Illustration to explain FIG. 10 is a diagram for explaining the operation of the moving mechanism unit according to the second embodiment, and is a diagram for explaining a state in which the moving lens frame is in contact with the retreat position regulating unit It is a figure explaining the effect | action of a moving mechanism part, and is a figure explaining the state which the nut with a convex part reverse | retreated and stopped after the moving lens frame contact | abutted to the retreat position control part.

Embodiments of the present invention will be described below with reference to the drawings.
A first embodiment of the present invention will be described with reference to FIGS.
As shown in FIG. 1, an electronic endoscope system 1 includes an electronic endoscope (hereinafter abbreviated as an endoscope) 2 provided with an imaging device, which will be described later, a light source device 3, a video processor 4, and a display. It is comprised with the color monitor 5 which is an apparatus. For example, the video processor 4 is provided with a power supply (not shown) that supplies power to a drive motor that drives a drive wire, which will be described later.

The endoscope 2 includes an insertion unit 6, an operation unit 7, and a universal cord 8 extending from the operation unit 7.
The insertion portion 6 is configured by connecting a distal end portion 9, a bending portion 10, and a flexible tube portion 11 in order from the distal end that is one end. A tip opening, an observation window, a plurality of illumination windows, a cleaning nozzle, and the like (not shown) are disposed on the tip surface of the tip portion 9. An imaging device is disposed on the back side of the observation window. In addition, a light guide bundle that transmits illumination light from the light source device 3 faces the back side of the plurality of illumination windows. In addition, the structure which arrange | positions light emitting elements, such as LED, instead of a ride guide bundle on the back side of an illumination window may be sufficient.

  The operation unit 7 includes an operation unit main body 12 that also serves as a gripping unit. The operation unit main body 12 includes a bending operation unit 15 including bending operation knobs 13 and 14, an air supply / water supply button 16, a suction button 17, It comprises a plurality of switches 18. The switch 18 is a switch that mainly controls the imaging function, and is displayed on the monitor 5, for example, an observation switching switch for switching the observation state to normal observation or magnified observation, a brightness switch for adjusting the brightness of the display image, and the like. An image recording switch for instructing recording of an endoscopic image, an image still switch for stopping the endoscopic image displayed on the monitor 5, and the like. Reference numeral 19 denotes a forceps opening, which communicates with a treatment instrument channel through which a treatment instrument such as a biopsy forceps is inserted.

  A scope connector 8 a is provided at the end of the universal cord 8, and the scope connector 8 a is detachably connected to the light source device 3. One end of the imaging device cable 20 is detachably connected to the side of the scope connector 8a. The other end of the imaging device cable 20 is detachably connected to the video processor 4.

  Reference numeral 21 denotes an operation unit. The operation unit 21 is formed of a sheet-like member 22 that can be sterilized. The operation unit 21 includes, for example, a first switch 23, a second switch 24, a third switch 25, and transmitters 23a, 24a, 25a corresponding to the switches 23, 24, 25. Each switch 23, 24, 25 and each transmitter 23 a, 24 a, 25 a are watertightly provided on the sheet-like member 22. The switches 23, 24, and 25 are composed of button type pressure-sensitive elements, and the operation surfaces of the switches 23, 24, and 25 are exposed on the surface of the sheet-like member 22.

  The operation unit 21 is attached to the operation unit 7 side of the insertion unit 6 or the operation unit side of the universal cord 8 in a wound state, for example, as indicated by a broken line in the figure. The signals output from the switches 23, 24, 25 are sent from the transmitters 23a, 24a, 25a to the receiver (not shown) of the light source device 3 or the receiver (not shown) of the video processor 4, for example. It is transmitted wirelessly.

  In the present embodiment, the first switch 23 is a switch for giving an instruction to switch the observation state to normal observation, and the third switch 25 is a switch for giving an instruction to switch the observation state to magnified observation. That is, in the electronic endoscope system 1 of the present embodiment, a switch for giving an instruction to switch the observation state can be attached in addition to the observation switch which is the switch 18 of the operation unit 7.

  The operation unit 21 is not limited to the observation changeover switch. For example, the operation unit 21 may be used instead of a foot switch, such as a switch for operating a high-frequency cautery device, a switch for operating an insufflation device, or the like. Is possible.

  Further, for example, by attaching a magnetic sheet to the back surface of the operation unit 21 and disposing a magnetic body on the operation unit 7 or the like of the endoscope 2, the operation unit 21 is attached to an arbitrary position of the operation unit 7 or the like. Is possible.

The imaging apparatus will be described with reference to FIGS.
As shown in FIG. 2, an imaging device 30 is provided at the distal end portion 9 of the insertion portion 6. Reference numeral 70 denotes a drive motor, and the drive motor 70 is provided in the operation unit 7.
As shown in FIGS. 2 and 3, the distal end portion 9 includes a distal end rigid member 26. The distal end rigid member 26 is formed with an imaging device arrangement hole 27, illumination holes 28a and 28b, a treatment instrument channel hole 29, and the like. Reference numeral 29a is a channel tube, and reference numeral 29b is a base.

As shown in FIG. 2, the imaging device 30 includes an element unit 31 and a lens unit 40.
The element unit 31 includes an image pickup element 32, an element frame 33, a first circuit board 34, a second circuit board 35, a signal cable 36, and an image pickup apparatus exterior frame (hereinafter referred to as an image pickup frame) 37. It is mainly prepared for.

  The image sensor 32 is a CCD, a CMOS, or the like. A cover lens 38 which is an optical member is bonded and fixed to the light receiving surface side of the image sensor 32. One surface of the cover lens 38 is disposed on the light receiving surface of the image sensor 32.

  The element frame 33 is made of, for example, stainless steel, and a cover lens 38 is integrally fixed to the inner surface of the element frame 33 by adhesion. A base end portion of a lens frame 41 (described later) constituting the lens unit 40 is disposed on the inner surface of the distal end portion of the element frame 33. The lens frame 41 and the element frame 33 are joined together by, for example, soldering after completing the position adjustment such as focusing.

  The first circuit board 34 is a laminated board, and the second circuit board 35 is a flexible printed board having flexibility, for example. Various electronic components (not shown) are mounted on the circuit boards 34 and 35. The image pickup device 32 is electrically connected to the first circuit board 34, and the signal line 36 a in the signal cable 36 is connected to the second circuit board 35.

  The signal cable 36 has a plurality of signal lines 36a inserted therein, and the base end portion of the signal cable 36 passes through the insertion portion 6, the operation portion 7, and the universal cord 8 and extends into the scope connector 8a.

  The imaging frame 37 covers the imaging device 32, circuit boards 34 and 35 on which electronic components are mounted, a part of the signal cable 36 connected to the second circuit board 35, and the like. The imaging frame 37 is configured by, for example, a heat shrinkable tube.

  The space in the imaging frame 37 is filled with an insulating sealing resin (not shown). The sealing resin includes a periphery of an electrical connection portion between the first circuit board 34 and the image sensor 32, a periphery of an electronic component mounted on the circuit boards 34 and 35, a periphery of the cover lens 38 and the image sensor 32, and a signal cable. The connection part between 36 and the second circuit board 35 is sealed.

  As shown in FIGS. 2 and 3, the lens unit 40 mainly includes a lens frame 41, a moving lens frame 42, and a moving lens frame moving mechanism unit (hereinafter abbreviated as a moving mechanism unit) 50. ing. The moving lens frame 42 moves back and forth to move a moving lens (to be described later) forward and backward with respect to the optical axis direction.

  The moving mechanism 50 includes a driving force transmission wire (hereinafter referred to as a drive wire) 51, a connecting member 52, a threaded shaft (hereinafter referred to as a lead screw) 53, a nut 54, and a front buffering portion. 55 and a rear buffer 56.

  The front buffer portion 55 is configured by a front spring 61 that is a first shock relaxation member, and the rear buffer portion 56 is a first rear spring 62 that is an advance position holding member and a second rear spring 63 that is a second shock relaxation member. It consists of The springs 61, 62, 63 are slidably disposed with respect to the lead screw 53.

  Reference numeral 43 denotes a slit, which is formed on the lens frame 41. In the slit 43, the protrusion 42a of the moving lens frame 42 is disposed. A front end side end surface of the slit 43 is a forward position restricting portion (hereinafter abbreviated as a wide end (W end)) 43a that restricts a forward position of the moving lens frame 42, and a base end side end surface of the slit 43 is a moving lens. A retraction position restricting portion (hereinafter abbreviated as a tele end (T end)) 43 b that restricts the retreat position of the frame 42.

  A through hole 42b is formed in the protrusion 42a. A lead screw 53 is inserted through the through hole 42b. Reference numeral 44 denotes a front lens, which is disposed in the front-end concave portion 41 a of the lens frame 41. Reference numeral 45 denotes a moving lens, which is disposed on the moving lens frame 42.

  Reference numeral 46 denotes a front holder, which is fixed to a predetermined position of the lens frame 41 on the front end side, for example. The front holder 46 is formed with a recess 46a in which the tip of the front spring 61 is disposed. Reference numeral 47 denotes a rear holder, which is fixed at a predetermined position on the front end side of the element frame 33, for example. The rear side holder 47 includes a distal end side recess 47a, a proximal end side recess 47b, and a communication hole 47c. The communication hole 47c communicates the distal end side recess 47a and the proximal end side recess 47b. The proximal end portions of the first rear spring 62 and the second rear spring 63 are arranged in the distal end side recess 47a. The lead screw 53 is inserted through the communication hole 47c.

  The drive wire 51 is a transmission member that transmits a rotational force, and has one end connected to the drive motor 70 to transmit a clockwise rotational drive force and a counterclockwise rotational drive force. A female screw member 52 a constituting the connecting member 52 is integrally fixed to the other end portion of the drive wire 51.

  The lead screw 53 is a shaft member, and is provided with a spiral projection that forms a male screw portion on the outer peripheral surface. A male screw member 52 b constituting the connecting member 52 is integrally fixed to one end portion of the lead screw 53.

  The other end of the lead screw 53 passes through the proximal recess 47b of the rear holder 47, the communication hole 47c, the distal recess 47a, and the through hole 42b of the moving lens frame 42 and rotates into the recess 46a of the front holder 46. Holds freely.

The male screw member 52b and the female screw member 52a are firmly and integrally fixed by, for example, applying an adhesive after screwing and fixing. Therefore, as the drive wire 51 rotates, the lead screw 53 fixed to the wire 51 also rotates as the wire 51 rotates.
The male screw member 52b and the female screw member 52a may be fixed by soldering instead of the adhesive.

  The nut 54 has a spiral groove that forms a female thread portion that is screwed into the spiral protrusion of the lead screw 53. The nut 54 is arranged in a screwed state with respect to the lead screw 53. The nut 54 also serves as a transmission state switching unit, and is configured to advance and retract on the lead screw 53 when the lead screw 53 rotates.

  Therefore, the nut 54 is restricted from rotating with the rotation of the lead screw 53 by a rotation prevention mechanism (not shown). Further, the nut 54 is disposed without contacting the proximal end surface of the front holder 46 and the distal end surface of the moving lens frame 42 in a state where the moving lens frame 42 is in contact with the W end 43a.

  As the rotation prevention mechanism, for example, a configuration including a convex portion provided on, for example, a wall of the imaging device arranging hole 27 and a concave portion formed on the nut 54 into which the convex portion is engaged, or provided on the wall. It is the structure by a recessed part and the convex part formed in the nut 54 engaged with this recessed part.

The front spring 61 which is the front buffer part 55 serves as a buffer member and a transmission state switching part, and is disposed on the tip side of the nut 54. The proximal end surface of the front spring 61 is in contact with the distal end surface of the nut 54. The front spring 61 has a predetermined spring force that presses the nut 54 against the moving lens frame 42 at all times. That is, the front spring 61 presses the nut 54 against the moving lens frame 42 and holds the contact state in a state where the nut 54 moves backward with the rotation of the lead screw 53 and contacts the moving lens frame 42. .
In the holding state, the rotational force of the lead screw 53 is transmitted to the moving lens frame 42 via the nut 54.

  The first rear spring 62 constituting the rear buffer portion 56 has a spring force that always urges the movable lens frame 42 toward the front end side. In a state where the nut 54 is separated from the moving lens frame 42, the first rear spring 62 abuts the moving lens frame 42 against the W end 43a by a spring force and holds the first rear spring 62 in a stable state.

  In the present embodiment, the second rear spring 63 is a buffer member, has a spring constant larger than the spring constant of the first rear spring 62, and is disposed, for example, on the inner side of the first rear spring 62. That is, the first rear spring 62 and the second rear spring 63 are arranged in parallel with the lead screw 53.

  The second rear spring 63 abuts against the base end surface of the moving lens frame 42 in a state where the first rear spring 62 is compressed by a predetermined amount as the moving lens frame 42 moves, and the frame 42 abuts against the T end 43b. This is a protective spring having a predetermined spring force that alleviates the impact.

  Comparing the first rear spring 62 with the second rear spring 63 disposed inside the first rear spring 62, the first rear spring 62 has a larger diameter than the second rear spring 63, and the length dimension is The first rear spring 62 is longer than the second rear spring 63. Further, in order to prevent the first rear spring 62 and the second rear spring 63 from being caught in the state in which the second rear spring 63 is disposed inside the first rear spring 62, the line length of the springs 62, 63 and The pitch is set at a predetermined value.

  The drive motor 70 is, for example, a stepping motor, and is set to rotate the nut 54 forward and backward on the lead screw 53 by rotating by a predetermined number of pulses more than the number of pulses corresponding to the moving distance.

  In this embodiment, when the observation with the endoscope 2 is started, the moving lens frame 42 of the lens unit 40 is abutted against the W end 43a and is in a normal observation state. Then, the movable lens frame 42 is moved and abutted against the T end 43b, so that an enlarged observation state is obtained. In this embodiment, the forward position restricting portion is the W end 43a. However, the optical system may be configured such that the forward position restricting portion becomes the T end.

The operation of the imaging device 30 including the lens unit 40 configured as described above will be described.
When the surgeon finds a polyp or the like in the normal observation state, the operator presses the third switch 25 of the operation unit 21, for example. Then, a signal is output from the transmitter 25 a and the signal is received by the receiver of the video processor 4, and the video processor 4 outputs a signal for switching the observation state to magnified observation to the drive motor 70.

The drive motor 70 rotates a motor shaft (not shown) clockwise at a predetermined rotational speed in order to move the moving lens 45 from the front to the rear.
The rotation of the motor shaft of the drive motor 70 is transmitted to the drive wire 51, and the drive wire 51 rotates as indicated by an arrow Y4a in FIG. Thereafter, the rotation of the drive wire 51 is transmitted to the nut 54 via the connecting member 52 and the lead screw 53.

  As a result, the nut 54 starts to move in the direction of the arrow Y4b alone, and then comes into contact with the tip surface of the moving lens frame 42 as shown in FIG. Then, the nut 54 moves the moving lens frame 42 toward the T end 43b at a predetermined speed as shown by the arrow Y5 against the spring force of the first rear spring 62. Thereafter, the moving lens frame 42 continues to move at a predetermined speed together with the nut 54 that moves as the lead screw 53 rotates.

  Then, when the first rear spring 62 is compressed by a predetermined amount as the moving lens frame 42 moves, the base end surface of the moving lens frame 42 contacts the second rear spring 63 as shown in FIG. Then, the moving speed of the moving lens frame 42 is gradually reduced by the spring force of the second rear spring 63. Thereafter, the moving lens frame 42 whose moving speed is decelerated hits the T end 43b as shown in FIG. As a result, the moving lens 45 is arranged at the magnification observation position, and the magnification observation image of the polyp is displayed on the screen of the monitor 5.

  The drive motor 70 continues to drive until the predetermined number of pulses is reached even after the moving lens frame 42 hits the T end 43b, and stops driving after reaching the predetermined number of pulses. After the drive is stopped, the moving lens frame 42 is held in a state where it abuts against the T end 43b.

  When the driving motor 70 is driven by a predetermined pulse while the moving lens frame 42 is in contact with the T end 43b, the motor 70 is in a sliding state and the load on the motor increases. To prevent. Further, when the moving lens frame 42 is in contact with the T end 43b, the springs 62 and 63 are compressed but do not come into close contact.

  When the observation with the enlarged observation image is completed, the surgeon presses the first switch 23 of the operation unit 21 in order to return the observation state to the original normal observation state. Then, a signal is output from the transmitter 23a, the signal is received by the receiver of the video processor 4, and the video processor 4 outputs a signal for switching (returning) the observation state to the normal observation state to the drive motor 70.

The drive motor 70 rotates a motor shaft (not shown) at a predetermined rotational speed counterclockwise in order to move the moving lens 45 from the rear to the front.
The rotation of the motor shaft of the drive motor 70 is transmitted to the drive wire 51, and the drive wire 51 rotates as indicated by an arrow Y7a in FIG. Thereafter, the rotation of the drive wire 51 is transmitted to the nut 54 via the connecting member 52 and the lead screw 53.

  As a result, the nut 54 starts to move in the direction of the arrow Y7b alone. Simultaneously with the start of movement of the nut 54, the moving lens frame 42 is pressed by the spring force of the first rear spring 62 and the spring force of the second rear spring 63, and the moving lens frame 42 also moves toward the W end 43a. Start.

  When the nut 54 continues to move due to the rotation of the lead screw 53, the second rear spring 63 is in a natural length state as shown in FIG. Thereafter, the moving lens frame 42 continues to move by the movement of the nut 54 and the spring force of the first rear spring 62, and abuts against the W end 43a as shown in FIG.

  At this time, the drive motor 70 continues to be driven until it reaches a predetermined number of pulses without being stopped simultaneously with the moving lens frame 42 hitting the W end 43a. That is, the nut 54 continues to move against the spring force of the front spring 61 after the movable lens frame 42 abuts against the W end 43a, moves away from the movable lens frame 42 as shown in FIG. It is moved to a position away from the base end face of 46 and stops.

  As described above, the rear buffer portion 56 is constituted by the first rear spring 62 and the second rear spring 63 having a predetermined spring force, so that the moving lens frame 42 moves toward the T end 43b at a predetermined speed. Can be decelerated immediately before coming into contact with the T end 43b, in other words, it can be brought into contact with the T end 43b in a state where the impact is reduced.

As a result, it is possible to prevent a problem that a large load is suddenly applied to the motor, the gears, and the like by the drive motor 70 being suddenly stopped. Therefore, the lifetime of the lens unit 40 including the first rear spring 62 and the moving lens frame 42 can be extended.
In addition, the moving speed of the moving lens frame 42 that moves backward can be further increased.

  In addition, by setting the number of pulses of the drive motor 70 to be increased by a predetermined ratio in advance, the spring force of the first rear spring 62 and the spring of the second rear spring 63 in the moving state toward the T end 43b side. The moving lens frame 42 can be reliably brought into contact with the T end 43b against the force.

  In addition, since the spring force increases and the moving speed of the moving lens frame 42 is reduced immediately before the moving lens frame 42 hits the T end 43b, the rotation of the drive motor 70 is gradually reduced. Later, when the drive motor 70 is driven by a predetermined number of pulses, it becomes slippery and the load on the motor can be reduced.

  On the other hand, in the state of movement toward the W end 43a, when the moving lens frame 42 abuts against the W end 43a, the drive motor 70 is not stopped and only the nut 54 is fixed by the driving force of the drive motor 70. Move by pulse. Therefore, when the moving lens frame 42 hits the W end 43a, an impact is transmitted from the moving lens frame 42 to the drive motor 70, and the lead screw 53, the drive wire 51, and the drive motor 70 are suddenly stopped by a sudden stop. It is possible to prevent a heavy load from being applied. In this way, since no overload is applied anywhere, the life of the lens unit 40 including the front spring 61 and the moving lens frame 42 can be extended.

A modification of the first embodiment will be described with reference to FIGS.
As shown in FIG. 8, the lens unit 40A of the present embodiment is different from the first embodiment in the configuration of the rear buffering portion 56A. That is, the rear buffer portion 56A includes a first rear spring 62A and a second rear spring 63A that have substantially the same outer diameter. The springs 62 </ b> A and 63 </ b> A are arranged in series with the lead screw 53 with the first rear spring 62 </ b> A approaching the moving lens frame 42.

  Thus, by arranging the springs 62A, 63A in series with the lead screw 53, the inner diameter dimension of the front-end-side recess 47a of the rear holder 47A is reduced, and the outer diameter of the rear holder 47A is indicated by a broken line. By reducing the outer diameter of the rear holder 47 of the first embodiment and reducing the dimension L of the imaging device 30 by the dimension t, it is possible to reduce the diameter of the distal end portion 9.

  In addition, by arranging the springs 62 </ b> A and 63 </ b> A in series with the lead screw 53, the hard length of the distal end portion 9 is increased. Therefore, when the feature required for the endoscope is reduced in diameter, a configuration is adopted in which two springs are arranged in series. When the feature required for the endoscope is to shorten the hard length, two springs are used. It is good to take the structure which arrange | positions in parallel.

Here, the operation of the lens unit 40A will be briefly described.
When the drive motor 70 is driven and the drive wire 51 starts to rotate as indicated by an arrow Y9a in FIG. 9, the rotation of the drive wire 51 is transmitted to the nut 54 via the connecting member 52 and the lead screw 53. The Then, the nut 54 moves alone in the direction of the arrow Y9b, and then comes into contact with the tip surface of the moving lens frame 42 as shown in FIG.

  Then, the nut 54 moves the moving lens frame 42 toward the T end 43b at a predetermined speed as shown by the arrow Y10 against the spring force of the first rear spring 62A. Thereafter, the moving lens frame 42 continues to move at a predetermined speed together with the nut 54 that moves as the lead screw 53 rotates.

  Then, the moving speed of the moving lens frame 42 is decelerated by the spring force of the second rear spring 63A in which the first rear spring 62A is brought into a substantially close contact state as shown in FIG. 11 as the moving lens frame 42 moves. The Thereafter, the moving lens frame 42 whose movement speed has been reduced hits the T end 43b as shown in FIG. As a result, the moving lens 45 is arranged at the magnified observation position, and the magnified observation image is displayed on the screen of the monitor 5.

  When the observation with the magnified observation image is completed, the surgeon returns the observation state to the original normal observation state. That is, the rotation of the motor shaft of the drive motor 70 is reversed as shown by the arrow Y12a in FIG. Thereafter, the rotation of the drive wire 51 is transmitted to the nut 54 via the connecting member 52 and the lead screw 53.

  As a result, the nut 54 starts to move in the direction of the arrow Y12b alone. Simultaneously with the start of movement of the nut 54, the moving lens frame 42 starts to move toward the W end 43a by being pushed by the spring force of the first rear spring 62A and the spring force of the second rear spring 63A.

  When the nut 54 continues to move due to the rotation of the lead screw 53, the second rear spring 63A is in a natural length state as shown in FIG. Thereafter, the moving lens frame 42 continues to move as the nut 54 moves due to the spring force of the first rear spring 62A, and the moving lens frame 42 abuts against the W end 43a as shown in FIG.

  The drive motor 70 is driven until the number of pulses reaches a predetermined number without being stopped at the same time as the moving lens frame 42 hits the W end 43a. Therefore, the nut 54 continues to move against the spring force of the front spring 61 after the movable lens frame 42 hits the T end 43b, and is separated from the movable lens frame 42 as shown in FIG. The holder 46 stops at a position separated from the base end surface of the holder 46.

  In this way, the rear buffer portion 56A is constituted by the first rear spring 62A and the second rear spring 63A having a predetermined spring force, and by arranging these springs 62A, 63A in series with the lead screw 53, Functions and effects similar to those of the first embodiment described above can be obtained.

  In the above-described embodiment, the first rear spring 62 </ b> A and the second rear spring 63 </ b> A having a predetermined spring force are arranged in series with respect to the lead screw 53 to constitute the rear buffer portion 56 </ b> A. However, as shown in FIG. 13, it is also possible to arrange the buffer spring 64 in which the first rear spring 62A and the second rear spring 63A are integrated so as to form the rear buffer portion 56B.

A second embodiment of the present invention will be described with reference to FIGS.
As shown in FIG. 14, the lens unit 40 </ b> B of the present embodiment mainly includes a lens frame 41, a moving lens frame 42 </ b> C, and a moving mechanism unit 80.

  The moving mechanism 80 includes a drive wire 51, a connecting member 52, a lead screw 53, a nut 81 with a convex portion, a balance plate 82, a front spring 83 that constitutes a front buffer 55B, and a rear buffer 56B. And a rear spring 84 constituting the.

  The other end portion of the lead screw 53 of this embodiment is screwed and arranged in a spiral groove 85 that forms a female screw included in the nut 81 with a convex portion. The nut 81 with a convex portion is a transmission state switching portion, and includes a nut body 86 having a spiral groove 85 and a cylindrical convex portion 87. The nut body 86 is formed with a concave portion (not shown) that engages with a convex portion (not shown) provided on the wall of the element frame 33, for example, as a rotation preventing mechanism. The convex portion 87 is inserted into a through hole 42b formed in the moving lens frame 42C so as to be able to advance and retreat with a predetermined fit.

  A concave portion 42d concentric with the through hole 42b is formed on the distal end side of the protrusion 42a of the moving lens frame 42C. A balance plate 82 is disposed in the recess 42d. The balance plate 82 is a transmission state switching portion that is slidable in the recess 42d, and is configured to close the opening on the front end side of the through hole 42b. In the present embodiment, when the lead screw 53 is rotated, the nut 81 with the convex portion moves forward and backward as indicated by the arrow Y14b, and the convex portion 87 moves in the through hole 42b and the concave portion 42d. And the front end surface of the convex part 87 is a structure which advances a predetermined amount in the state which contact | abutted against the balance plate 82. FIG.

  Reference numeral 88 denotes a rotation holding block. The rotation holding block 88 has a purpose of holding the lead screw 53 to obtain a stable rotation and a movement position of the base end surface of the nut 81 with the protrusion, and a protrusion 87 that can be protruded and retracted through the through hole 42b. It is prevented from falling off from the base end side opening of the hole 42b.

  The front end of the front spring 83 is disposed in the recess 46 a of the front holder 46. The proximal end portion of the front spring 83 is disposed in the recess 42 d of the moving lens frame 42 </ b> C, and the proximal end surface thereof abuts on the distal end surface of the balance plate 82.

  The front spring 83 is a first impact relaxation member and has a predetermined spring force that always presses the balance plate 82. In a state where the balance plate 82 is pressed by the spring force of the front spring 83, the spring force is transmitted to either the front end surface of the convex portion 87 or the bottom surface of the concave portion 42d of the moving lens frame 42C. It has become. The front spring 83 abuts the moving lens frame 42C against the T end 43b with a spring force in a stable state. As a result, an enlarged observation state can be obtained.

The rear spring 84 is a second impact mitigating member, and is inserted and disposed in the convex portion 87, and has a predetermined spring force that constantly presses the moving lens frame 42C toward the front end side. In the present embodiment, the rear spring 84 pushes the movable lens frame 42C in a stable state to the W end 43a by the spring force when the balance plate 82 is separated from the bottom surface of the recess 42d and the base end surface of the front holder 46. Hit it. As a result, a normal observation state can be obtained.
Reference numeral 89 denotes a stopper for setting the T end 43b.

Here, an operation of the lens unit 40B including the moving mechanism unit 80 will be briefly described.
When the drive motor 70 is driven and the drive wire 51 starts to rotate as indicated by the arrow Y14a in FIG. 14, the rotation of the drive wire 51 is caused by the projecting nut 81 via the connecting member 52 and the lead screw 53. Is transmitted to.

  Then, the nut 81 with a convex part starts retreating toward the rotation holding block 88 as shown by an arrow Y15 in FIG. Then, the balance plate 82 pressed by the front spring 83 comes into contact with the bottom surface of the concave portion 42d of the moving lens frame 42C.

  Then, the spring force of the front spring 83 is transmitted to the moving lens frame 42C, and the spring force of the front spring 83 and the spring force of the rear spring 84 are balanced, and the moving lens frame 42C is in the T end of the stopper 89. The movement is started at a predetermined speed toward 43b.

  Then, as shown in FIG. 16, the moving lens frame 42 </ b> C hits the T end 43 b of the stopper 89. As a result, the moving lens 45 is arranged at the magnified observation position, and the magnified observation image is displayed on the screen of the monitor 5.

  Even after the moving lens frame 42C hits the T end 43b of the stopper 89, the drive motor 70 is driven until reaching the predetermined number of pulses without being stopped, and stops driving after reaching the predetermined number of pulses. That is, after the moving lens frame 42C hits the T end 43b, the drive motor 70 has a problem that the impact force is transmitted and a problem that the load rapidly increases by retracting the nut 81 with the convex portion by a predetermined amount. It is preventing.

  On the other hand, when the observation with the enlarged observation image is completed, the surgeon returns the observation state to the original normal observation state. That is, the rotation of the motor shaft of the drive motor 70 is reversed as shown by the arrow Y17a in FIG. Thereafter, the rotation of the drive wire 51 is transmitted to the nut 81 with the convex portion via the connecting member 52 and the lead screw 53.

  As a result, the nut 81 with the convex portion starts to move in the direction of the arrow Y 17 b alone against the urging force of the rear spring 84, and the distal end surface of the convex portion 87 comes into contact with the base end surface of the balance plate 82. Then, the spring force of the front spring 83 and the spring force of the rear spring 84 are in balance, and the moving lens frame 42C starts moving toward the W end 43a as the convex nut 81 moves. And the nut 81 with a convex part continues advancing movement by rotation of the lead screw 53, As a result, the moving lens frame 42C hits the W end 43a as shown in FIG.

  The drive motor 70 is driven until the number of pulses reaches a predetermined number without being stopped simultaneously with the moving lens frame 42C hitting the W end 43a. Therefore, the convex nut 81 moves the balance plate 82 toward the front holder 46 against the spring force of the front spring 83 after the movable lens frame 42C hits the W end 43a, and is shown in FIG. As described above, the moving lens frame 42C stops at a position away from the bottom surface of the recess 42d and also away from the base end surface of the front holder 46.

  Thus, the front spring 83 having a predetermined spring force that is the front buffer portion 55B and the rear spring 84 having the predetermined spring force that is the rear buffer portion 56B are opposed to each other with the moving lens frame 42C interposed therebetween. Then, the rotation of the lead screw 53 moves the nut 81 with the convex portion to bring the balance plate 82 into contact with the bottom surface of the concave portion 42d, and the movable lens frame is in a state where the front spring 83 and the rear spring 84 are balanced. 42C is moved to abut against the T end 43b and the W end 43a. After the abutment, only the nut 81 with the convex portion is moved, and the impact force when the movable lens frame 42 abuts against the T end 43b or the W end 43a is transmitted to the drive motor 70. In addition, it is possible to prevent a sudden load from being applied to the lead screw 53, the drive wire 51, and the like, thereby extending the life of the lens unit 40B including the moving lens frame 42.

  In the above-described embodiment, the lead screw 53 is rotated by the drive motor 70 to move the moving lens frames 42 and 42C. However, the lens unit 40 including the moving mechanism units 50 and 80 described above is also used in the configuration in which the moving state of the moving lens frames 42 and 42C is changed, for example, by moving the operation wire by tilting or rotating the manual lever. , 40A, 40B can exert the same effect and extend the life of the lens units 40, 40A, 40B.

  In the present invention, a spring is taken as an example of a cushioning material such as a front cushioning portion or a rear cushioning portion, but the cushioning material may be replaced with a silicon rubber tube, for example. As described above, the present invention is not limited to the embodiments described above, and various modifications can be made without departing from the scope of the invention.

DESCRIPTION OF SYMBOLS 1 ... Electronic endoscope system 2 ... Endoscope 3 ... Light source device 4 ... Video processor 5 ... Color monitor 6 ... Insertion part 7 ... Operation part 8 ... Universal cord 8a ... Scope connector 9 ... Tip part 10 ... Bending part 11 ... Flexible tube section 12 ... operation section main body 13, 14 ... bending operation knob 15 ... bending operation section 16 ... air / water supply button 17 ... suction button 18 ... switch
DESCRIPTION OF SYMBOLS 20 ... Cable for imaging device 21 ... Operation unit 22 ... Sheet-like member 23, 24, 25 ... Switch 23a, 24a, 25a ... Transmitter 26 ... Hard end member 27 ... Imaging device arrangement hole 28a, 28b ... Illumination hole 29 ... treatment instrument channel hole 29a ... channel tube 29b ... base 30 ... imaging device 31 ... element unit 32 ... imaging element 33 ... element frame 34 ... first circuit board 35 ... second circuit board 36 ... signal cable 36a ... signal line 37 ... Imaging frame 38 ... Cover lens 40 ... Lens unit 41 ... Lens frame 41a ... Tip side recess 42 ... Moving lens frame 42a ... Projection part 42b ... Through hole 42d ... Recess 43 ... Slit 43a ... Advance position restricting part (W end)
43b ... Retraction position restricting portion (T end) 44 ... Front lens 45 ... Moving lens 46 ... Front holder 46a ... Recess 47 ... Rear holder 47a ... Front side recess 47b ... Base end side recess 47c ... Communication hole 50 ... Moving mechanism
51 ... Drive wire 52 ... Connecting member 52a ... Female screw member
52b ... male screw member 53 ... lead screw 54 ... nut 55 ... front side buffer part 56 ... rear side buffer part 61 ... front spring 62 ... first rear spring 63 ... second rear spring
64 ... buffer spring 70 ... drive motor 80 ... moving mechanism part 81 ... nut with convex part
82 ... Balance plate 83 ... Front spring 84 ... Rear spring 85 ... Spiral groove 86 ... Nut body 87 ... Convex part 88 ... Rotation holding block 89 ... Stopper

Claims (4)

A moving lens frame that includes an optical lens, is movable forward and backward in the direction of the optical axis, and is defined by the position restricting portion at a forward position and a backward position;
An advancing position holding member that is disposed in contact with the base end surface of the moving lens frame and has a holding force to hold the moving lens frame in the advancing position at all times;
A moving lens frame moving mechanism for moving the moving lens frame by manual power or actuator power;
When the power is transmitted from the moving lens frame moving mechanism unit to the moving lens frame to move the moving lens frame forward or backward, or when the moving lens frame moving forward or backward reaches the forward position or the backward position, the moving lens A transmission state switching unit that switches to a state in which impact force is not transmitted from the frame to the moving lens frame moving mechanism unit ,
The moving lens frame moving mechanism section is
A transmission member for transmitting rotational force;
A shaft member having an external thread formed on the outer peripheral surface;
A connecting member that connects the shaft member and the transmission member so that power is transmitted;
A nut that is a transmission state switching portion that forms a female screw portion that is screwed to the male screw portion of the shaft member, can move forward and backward with respect to the shaft member, and is disposed on the distal end side of the moving lens frame. When,
The nut is disposed in contact with the front end surface of the nut, has a holding force to constantly press the nut against the moving lens frame, and reduces the impact when the moving lens frame hits the advance position of the position restricting portion. 1 impact mitigating member;
The moving lens frame has an elastic constant larger than the elastic constant of the advance position holding member that abuts before the position restricting portion hits the retracted position of the position restricting portion and alleviates an impact when the moving lens frame hits the retracted position. A second impact relaxation member,
The nut and the first impact relaxation member also serve as the transmission state switching unit . The imaging apparatus according to claim 1, wherein the advance position holding member and the second impact relaxation member are arranged in parallel on the retracted position side of the moving lens frame . The imaging apparatus according to claim 1, wherein the advance position holding member and the second impact relaxation member are arranged in series on the retracted position side of the moving lens frame . The imaging apparatus according to claim 3, wherein the advance position holding member and the second impact relaxation member are integrally configured .

Images