JP4426770B2 - Endoscope holding device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an endoscope holding apparatus used for installing an endoscope for use in various operations such as ophthalmology and neurosurgery in the medical field.
[0002]
[Prior art]
In general, in the field of endoscopic surgery, a method is adopted in which an endoscope is fixedly arranged corresponding to an operation site, and treatment of the operation site is performed while moving and adjusting the endoscope. Such an endoscope is fixedly arranged through a holding means that can be moved and adjusted three-dimensionally. By controlling the driving of the fixing means, the observation field of the endoscope is opposed to a desired surgical site. (See Patent Document 1).
[0003]
However, in the above holding means, when an endoscope having a different perspective angle is used in an interchangeable manner as a usage form of the endoscope, the driving direction of the observation visual field is changed according to the perspective angle of the endoscope. Due to the difference, the observation visual field adjustment becomes very complicated and has the disadvantage that the usability is inferior.
[0004]
In the field of surgical microscopes, a visual field moving mechanism for adjusting the observation visual field of the microscope main body electrically is provided. In such a surgical microscope, the observation direction may not coincide with the driving direction of the visual field movement mechanism, and it is necessary to operate the operation unit in consideration of the amount of deviation in that direction.
[0005]
Therefore, in the surgical microscope, the amount of deviation between the observation direction and the driving direction of the visual field moving mechanism is detected by a sensor, and the operation direction of the operation unit and the actual visual field are detected based on the detected value. A configuration that controls the driving direction of the visual field moving mechanism so as to match the moving direction has also appeared (see Patent Document 2).
[0006]
However, in the surgical microscope described above, for example, the operator's standing position or the operation unit placement position is detected because of the configuration in which the state of the holding means that holds the mirror is detected and the drive direction is corrected based on the detection result. Therefore, it is inconvenient that the usability is inferior.
[0007]
[Patent Document 1]
Japanese Patent No. 3298013
[0008]
[Patent Document 2]
JP-A-6-230289
[0009]
[Problems to be solved by the invention]
As described above, in the conventional endoscope holding means of the conventional technique, since the endoscope having a different usage angle is used interchangeably, the observation visual field adjustment corresponding to the perspective angle is performed. It has the disadvantage that the burden on the surgeon is large.
[0010]
In the latter case, since the operator is restrained by the standing position, the usability is inferior.
[0011]
The present invention has been made in view of the above circumstances, and is an endoscope that can easily and easily realize adjustment of an observation visual field of an endoscope having different perspective angles and can improve usability. An object is to provide a holding device.
[0012]
[Means for Solving the Problems]
The present invention relates to a plurality of endoscopes having different field planes for observing a subject, a holding means in which any of the plurality of endoscopes is held in a three-dimensional manner so as to be movable and adjustable, and held in the holding means A moving means for moving the endoscope made in three axial directions orthogonal to the holding means, an operating means for operating the moving means to move the observation field of view of the endoscope, and the endoscope Control the movement of the endoscope by driving the moving means based on the input of the operation means while maintaining the deflection state according to each deflection state of the observation field of the mirror with respect to the subject and the three axis directions. Control means to An image pickup device for picking up an image of the subject observed by the endoscope, and processing and displaying the image picked up by the image pickup device, according to the observation field of view of the endoscope Imaging display means for moving the imaging device and adjusting the imaging position; An endoscope holding apparatus was configured.
[0013]
According to the above configuration, in accordance with each deflection state of the observation visual field direction with respect to the subject of the endoscope and the three axis directions orthogonal to each other, the deflection state Keep By controlling the movement of the endoscope by driving the moving means based on the input of the operating means, the observation field of view of the endoscope matches the operating direction of the operating means. Therefore, since the operation direction of the operating means corresponds to the observation field of the endoscope, the observation field can be adjusted according to the perspective angle of the endoscope without being affected by the standing position, and the convenience of the operator is improved. Can be improved.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0015]
(First embodiment)
FIG. 1 shows an endoscope holding apparatus according to a first embodiment of the present invention. A stand 1 is erected on a base 2 that is movable with respect to a floor surface (not shown). One end of the first arm 3 is rotatably arranged around the axis A at the front end of the stand 1, and an intermediate portion of the second arm 4 is provided at the other end of the first arm 3. It is arranged so as to be rotatable around the axis B. One end of the third arm 5 is disposed at one end of the second arm 4 so as to be rotatable around the axis C. At the other end of the third arm 5, one end of the fourth arm 6 is disposed so as to be rotatable around a coaxial axis D.
[0016]
In the fourth arm 6, a ball 8 constituting a ball joint mechanism is arranged freely around the axis E on the peripheral wall of the other end, and a housing 9 is attached to the ball 8. The housing 9 is provided with a grip portion 10, and an intermediate portion of the endoscope 11 is detachably attached to the grip portion 10. A TV camera head 12 is attached to one end of the endoscope 11. The TV camera head 12 captures an observation image captured by the endoscope 11.
[0017]
A camera control unit (CCU) 13 is connected to the TV camera head 12, and a TV monitor 14 is connected to the CCU 13. The TV camera head 12 is driven and controlled via the CCU 13, and when an observation image captured by the endoscope 11 is captured, the observation image is displayed on the TV monitor 14 via the CCU 13.
[0018]
In addition, an operation foot switch unit 15 is disposed in the vicinity of the stand 1. The foot switch unit 15 is provided with a joystick switch 16 having a four-way switch for moving the observation field of view of the endoscope 11 on the TV monitor 14 in the vertical and horizontal directions, for example.
[0019]
Further, the stand 1 is provided with a control electromagnetic valve 19 (see FIG. 2). One end of an air hose 17 is connected to the electromagnetic valve 19, and a switch 20 is connected to the control signal input end via an air brake control circuit 18. The output end of the solenoid valve has first to fifth air brakes for driving the shaft. 181 to 185 Is connected.
[0020]
The switch 20 is disposed in the housing 9 and controls the solenoid valve 19 via an air brake control circuit 18 in conjunction with the switching operation, and the air from the air hose 17 is supplied to the first to fifth air brakes. By selectively supplying to 181 to 185, the release of the fixing of the first to fourth arms 3 to 6 around the axes A to C and the axis 8 of the ball 8 is executed.
[0021]
Here, a visual field moving mechanism for moving the endoscope 11 around three axes orthogonal to each other will be described.
[0022]
That is, the housing 9 is provided with an X-axis housing 21, a Y-axis housing 22, and a Z-axis housing 23, and the X-axis housing 21 is integrally provided with the balls 8 constituting the ball joint mechanism. An X-axis motor 211 is attached to the X-axis housing 21, and a pinion gear 212 is attached to the motor shaft of the X-axis motor 211. The pinion gear 212 is meshed with the X-axis rack gear 213 so as to be freely meshed. The X-axis rack gear 213 is attached to a slit 214 provided in the X-axis housing 21 so as to be slidable in the X-axis direction. Therefore, when the X-axis motor 211 is driven clockwise, the X-axis rack gear 213 is moved along the slit 214 of the X-axis housing 21 in the direction indicated by the arrow X in FIG.
[0023]
The Y-axis housing 22 is attached to the X-axis rack gear 213. A Y-axis motor 221 is attached to the Y-axis housing 22, and a pinion gear 222 is attached to the motor shaft of the Y-axis motor 221. A Y-axis rack gear 223 is meshed with the pinion gear 222. The Y-axis rack gear 223 is disposed substantially orthogonal to the X-axis rack gear 213.
[0024]
The Y-axis rack gear 223 is attached to a slit 224 provided in the Y-axis housing 22 so as to be slidable in the arrow Y direction. When the Y-axis motor 221 is driven clockwise, the Y-axis rack gear 223 is inserted into the slit 224 of the Y-axis housing 22. Along the direction of arrow Y in FIG.
[0025]
The Z-axis housing 23 is attached to the Y-axis rack gear 223. A Z-axis motor 231 is attached to the Z-axis housing 23, and a pinion gear 232 is attached to the motor shaft of the Z-axis motor 231. A Z-axis rack gear 233 is meshed with the pinion gear 232. The Z-axis rack gear 233 is disposed substantially orthogonal to the Y-axis rack gear 223 and the X-axis rack gear 213.
[0026]
The Z-axis rack gear 233 is attached to a slit 234 provided in the Z-axis housing 23 so as to be slidable in the arrow Z direction. When the Z-axis motor 231 is driven clockwise, the slit of the Z-axis housing 23 is provided. It is driven in the direction of arrow Z in FIG.
[0027]
The Z-axis rack gear 233 is provided with the grip portion 10. The endoscope gripping direction of the gripping unit 10 is coincident with the arrow Z direction in FIG. 3, and the endoscope 11 is selectively inserted.
[0028]
The grip 10 includes an encoder 24 that detects the rotation direction of the endoscope 11. As shown in FIG. 4, the encoder 24 is connected to, for example, a driving direction calculation unit 25 built in the stand 1, and the joystick switch 16 of the foot switch unit 15 connects the cable 161 to the driving direction calculation unit 25. Connected through.
[0029]
In addition, an endoscope perspective angle setting unit 26 and an observation direction setting unit 27 are connected to the driving direction calculation unit 25. The motor drive unit 28 is connected to the output end of the drive direction calculation unit 25, and the X-axis motor 211, the Y-axis motor 221 and the Z-axis motor 231 are connected to the motor drive unit 28, respectively.
[0030]
The observation direction setting unit 27 is operably disposed on the housing 9 as shown in FIG. 5, for example, and the observation direction (standing position) of the operator 100 can be selectively set by adjusting the operation direction. It has become.
[0031]
Here, the relationship between the observation direction (standing position) and the observation field of view for each endoscope will be described with reference to FIG. In other words, the relationship between the operator 100 and the endoscope 11 is that when the observation direction (standing position) of the operator 100 is set, in the case of the direct-view type endoscope 11, the viewing field A is obtained, and FIG. 2), the two axes of the TV monitor 14 correspond to the X-axis and Y-axis directions of the three axes (X-axis, Y-axis, and Z-axis). In the case of a perspective type, for example, 90 °, when the endoscope 11 is directed in the B direction and the C direction at intervals of 90 °, the observation field of view is changed to B and C, and the two axes of the TV monitor 14 are This corresponds to the Y axis and the Z axis (see FIG. 7B), and the X axis and the Z axis (see FIG. 7C). When the direct-view type endoscope 11 is oriented in the direction perpendicular to the plane of the paper (D direction), the viewing field is changed to D, and the two axes of the TV monitor 14 correspond to the X axis and the Y axis (see FIG. 7D). The
[0032]
In the above configuration, the visual field operation procedure will be described with reference to FIG. First, the operator 100 operates the observation direction setting unit 27 to set the observation direction (standing position) (step S1). For example, it is set that the observation direction of the operator 100 is observation from a direction parallel to the Y axis of the housing 9. Subsequently, in step S <b> 2, the endoscope 11 having a desired perspective angle is inserted into the grip portion 10. Then, the surgeon 100 selectively operates the endoscope perspective angle setting unit 26 to set the perspective of the endoscope 11 that has been inserted.
[0033]
Here, for example, in the case of the direct-view endoscope 11, as shown in FIG. 9A, the observation direction corresponding to the standing position of the operator 100 and the three axes (X Axis, Y axis, Z axis). At this time, the observation image displayed on the TV monitor 14 has the relationship shown in FIG. 9B with respect to the X axis and the Y axis. Here, the observation direction of the surgeon is the same direction as the visual field movement direction (X axis, Y axis, Z axis) of the housing 9 when viewed from the left side of the drawing.
[0034]
Subsequently, the process proceeds to step S3 and the switch 20 of the housing 9 is operated. Then, an operation signal of the switch 20 is output to the air brake control circuit 18, and an open signal is output from the air brake control circuit 18 to the electromagnetic valve 19. Here, the solenoid valve 19 selectively supplies the compressed air supplied from the air hose 17 to the air brakes 181 to 185. As a result, the air brakes 181 to 185 are shifted from the fixed state to the released state, and the first to fourth arms 3 to 6 and the axes A to E of the ball 8 are set to a free state. The fourth to third arms 3 to 6 and the ball 8 are moved to move the endoscope 11 to a desired position to be observed. Here, the supply of compressed air to the air brakes 181 to 185 is cut off and switched to a fixed state to lock the first to fourth arms 3 to 6 and the ball 8.
[0035]
In step S4, the operator 10 rotates the endoscope 11 and sets, for example, the TV monitor 14 so that the top of the screen is at the back and the bottom of the screen is at the front. Is set to a reference value (= 0) (step S5). Thereafter, the encoder 24 detects the rotation angle of the endoscope 11 from the reference value (= 0) and outputs the rotation angle information to the drive direction calculation unit 25 (step S6).
[0036]
Here, the surgeon 100 moves the field of view while moving the field of view, for example, while viewing the image (shown in FIG. 9B) of the TV monitor 14 electrically to advance the treatment. The joystick switch 16 of the unit 15 is operated and moved. Then, the operation signal of the joystick switch 16 is transmitted to the drive direction calculation unit 25.
[0037]
The drive direction calculation unit 25 sets the drive direction according to the states of the encoder 24, the endoscope perspective angle setting unit 26, and the observation direction setting unit 27. That is, when moving the visual field upward from the observation direction of the operator 100, a control signal for driving the Y-axis motor 221 counterclockwise is output to the motor drive unit 28. The Y-axis motor 221 is driven counterclockwise, and the Y-axis rack gear 223 is moved in the Y-direction (direction away from the operator 100) in FIG. Accordingly, the visual field is moved upward on the TV monitor 14.
[0038]
Similarly, when the operator 10 operates the joystick switch 16 so as to move the visual field to the left, the drive direction calculation unit 25 outputs a control signal for driving the X-axis motor 211 clockwise to the motor drive unit 28. To do. The X-axis motor 211 is driven clockwise, and the X-axis rack gear 213 is moved in the X + direction (leftward as viewed from the operator 100) in FIG. Thereby, the field of view of the endoscope 11 is moved to the left also on the TV monitor 14. Then, the observation image of the endoscope 11 is taken by the TV camera head 12 as described above and displayed on the TV monitor 14 via the CCU 13. Here, the surgeon 100 treats the surgical site while observing the observation image displayed on the TV monitor 14.
[0039]
Next, when observing the front side of the surgical site, the operator 100 first pulls the direct-view endoscope 11 from the grip 10 and inserts the endoscope 111 having a perspective angle of 90 ° into the grip 10. To wear. In this usage pattern, first, the operator 100 sets that the perspective angle of the endoscope 111 is 90 ° by the endoscope perspective angle setting unit 26. In the case of this endoscope 11, the endoscope 111 and the surgical part of the subject are connected to each other between the observation direction corresponding to the standing position of the operator 100 and the endoscope 11 as shown in FIG. It has a relationship to three orthogonal axes (X axis, Y axis, Z axis). At this time, the observation image displayed on the TV monitor 14 has the relationship shown in FIG. 10B with respect to the X axis and the Z axis.
[0040]
In this mode of use, for example, when the surgeon 100 moves his hand to the right, the hand moves to the left on the image of the TV monitor 14, so the surgeon 100 presses an image inversion function switch (not shown) provided in the CCU 13. Operate and invert the image to a mirror image. Thereby, the image of the TV monitor 14 is set as shown in FIG. 10B, and the treatment is performed while observing this image. When the operator 100 operates the joystick switch 16 so as to move the visual field upward, the drive direction calculation unit 25 outputs a control signal for driving the Z-axis motor 231 clockwise to the motor drive unit 28. . The Z-axis motor 231 is driven clockwise, and the observation field of view is moved upward on the TV monitor 14 by moving the Z-axis rack gear 233 in the Z + direction in FIG.
[0041]
Further, the operator 100 rotates the endoscope 111 by 90 ° in the clockwise direction when observing the left side direction of the surgical site. This amount of rotation is detected by the encoder 24, and this detection signal is input to the drive direction calculation unit 25. In this case, as shown in FIG. 11A, the endoscope 111 and the operative part of the subject are in the three directions (three axes orthogonal to the observation direction corresponding to the standing position of the operator 100 and the endoscope 11). X axis, Y axis, Z axis). At this time, the observation image displayed on the TV monitor 14 has the relationship shown in FIG. 11B with respect to the Y axis and the Z axis. Therefore, since the operator 100 is positioned in a direction that facilitates treatment, the operator 100 moves the position toward the front of the page, and sets the fact by the observation direction setting unit 27.
[0042]
In this usage pattern, the image reversal function switch (not shown) of the CCU 13 is operated to match the direction of movement of the hand of the operator 100 and the direction of movement of the image on the TV monitor 14, and the image is changed from a mirror image to a normal image. Return to. Thus, when the operator 100 operates the joystick switch 16 so as to move the visual field in the left direction, the drive direction calculation unit 25 outputs a control signal for driving the Y-axis motor 221 clockwise to the motor drive unit 28. . Then, the Y-axis motor 221 is driven clockwise, and the Y-axis rack gear 223 is moved in the Y + direction in FIG. Thereby, in the TV monitor 14, the observation visual field is moved in the left direction.
[0043]
With respect to the other directions, for example, as shown in FIG. 12, the TV monitor depends on three factors: the perspective angle of the endoscopes 11 and 111, the rotation angle of the endoscopes 11 and 111 with respect to the housing 9, and the observation direction of the operator. The viewing field direction on 14 is uniquely determined.
[0044]
In this way, the endoscope holding apparatus is configured to input the deflection state and the operation means according to the deflection state of the observation visual field direction with respect to the subject of the endoscopes 11 and 111 and the three axial directions orthogonal to each other. The X axis motor 211, the Y axis motor 221 and the Z axis motor 231 are driven based on the control to control the movement of the endoscope 11 in the three axis directions, and the observation field of the endoscope 11 and the operation direction of the joystick switch 16 are controlled. Was configured to match. According to this, since the operation direction of the joystick switch 16 corresponds to the observation visual field of the endoscope 11, the observation visual field can be adjusted according to the perspective angle of the endoscope 11, and the usability of the operator 100 is improved. Can be achieved.
[0045]
In other words, since the correction means for automatically correcting the observation visual field direction according to the observation direction including the perspective direction of the endoscopes 11 and 111 is provided, there is no sense of incongruity between the observation direction and the observation visual field direction. Can be executed efficiently. Moreover, since the observation visual field can be moved without worrying about the perspective angle, the rotation angle of the endoscopes 11 and 111 and the observation direction of the operator 100, the visual field can be easily moved, and the operation time can be shortened. I can plan.
[0046]
In the above embodiment, the operator 100 manually switches between the mirror image and the normal image in order to match the direction of the image displayed on the TV monitor 14 and the actual operation direction. This is semi-automatic. It is also possible to configure as described above.
[0047]
For example, in the usage pattern in which the endoscope 111 having a 90 ° perspective angle is used, a front view, a mirror image, and a forward view are normal images. (In the case of direct viewing, a mirror image is not required and a squint is detected.) Since the “shift” between the rotation angle and the observation direction of the operator can be identified by detection or setting, an image is automatically generated according to the identification. May be switched between a mirror image and a normal image.
[0048]
Further, in the above-described embodiment, the case where the endoscope is configured using an endoscope having a perspective angle of 90 ° has been described. However, the present invention is not limited thereto, and for example, an endoscope 11a having a perspective angle of 30 ° as illustrated in FIG. It is also possible to configure using In this case, the endoscope 11a having a perspective angle of 30 ° disposed on the grip portion 10 of the housing 9 has an X axis ((1 / (1/1/1)) so that the observation field of view is orthogonal to the detection surface as shown in FIG. 2) The movement is controlled by the relationship of (Z)-((√3 / 2) · Y) axis.
[0049]
(Second Embodiment)
15 to 19 show an endoscope holding apparatus according to the second embodiment of the present invention, and the same effects as those of the first embodiment are expected. However, in FIGS. 15 to 19, the same parts as those in FIGS. 1 to 4 are denoted by the same reference numerals, and detailed description thereof is omitted.
[0050]
That is, the grip portion 10 disposed in the housing 9 has endoscope selection first and second recesses 102 and 103 at one end of an endoscope insertion portion 101 as shown in FIG. The first and second recesses 102 and 103 are provided with an interval (for example, an interval of about 90 ° with respect to the endoscope insertion portion 101). 30, 31 are arranged (see FIG. 18). One of the direct-view endoscope 11 (see FIG. 16) or the perspective endoscope 111 (for example, a 90 ° perspective endoscope) (see FIG. 17) is selected for the endoscope insertion hole 101 of the grip 10. And is attached at a predetermined position using a fixing knob (not shown).
[0051]
Of these, the direct-view endoscope 11 has a ring-shaped first guide member 32 rotatably mounted on the mirror body. The first guide member 32 has a protrusion 321 to be detected. Is provided corresponding to the first recess 102 of the grip 10. When the direct-view endoscope 11 is inserted into the endoscope insertion portion 101 of the grip portion 10, the first guide member 32 is accommodated in the first recess 102 of the grip portion 10. Only the first micro switch 30 is turned on.
[0052]
Further, a ring-shaped second guide member 33 is rotatably fitted to the perspective microscope 111, and the first and second protrusions 331 and 332 are provided on the second guide member 33, respectively. It is provided corresponding to the first and second recesses 102 and 103 of the grip 10. When the perspective endoscope 111 is inserted into the endoscope insertion portion 101 of the grip portion 10, the second guide member 33 has the first and second protrusions 331 and 332 of the grip portion 10. The first and second recesses 102 and 103 are accommodated substantially simultaneously, and in the accommodated state, both the first and second micro switches 30 and 31 are turned on.
[0053]
As shown in FIG. 18, the first and second micro switches 30 and 31 are connected to a driving direction calculation unit 34, and the driving direction calculation unit 34 is connected to the X-axis motor via the motor driving unit 28. 211, a Y-axis motor 221 and a Z-axis motor 231 are connected. The drive direction calculation unit 34 is built in, for example, the stand 1 and is connected to the output end of the navigation device 35 for detecting the observation direction, the endoscope tip position, and the housing position.
[0054]
For example, as shown in FIG. 19, the navigation device 35 analyzes a digitizer 351 having a plurality of imaging elements that receive infrared rays and the light reception signal, and calculates the detection of the relative position between the site where the LED light emitting unit is arranged. A workstation (hereinafter referred to as WS) 352 is configured. The output end of the WS 352 is connected to the drive direction calculation unit 34.
[0055]
On the other hand, the housing 9 is provided with a first LED light emitting unit 353 in which, for example, three infrared LEDs are arranged at the apex of a triangle, and the TV camera head 12 assembled to the endoscopes 11 and 111 includes Similarly, a second LED light emitting unit 354 is provided in which three infrared LEDs are arranged at the apex of a triangle. The surgeon 100 is similarly provided with a third LED light emitting unit 355 in which three infrared LEDs are provided at the apex of the triangle, attached to, for example, glasses.
[0056]
The first to third LED light emitting units 353, 354, and 355 are driven via a drive control unit (not shown) to emit infrared rays. Then, the infrared rays emitted from the first to third LED light emitting units 353, 354, and 355 are imaged by the digitizer 351 of the navigation device 35. The digitizer 351 performs image analysis on the captured infrared images from the first to third LED light emitting units 353, 354, and 355, and outputs the analysis information to the WS 352. The WS 352 is based on the infrared image analysis information from the first to third LED light emitting units 353, 354, and 355 sent from the digitizer 351, and the position / posture information of the housing 9 and the rotation of the endoscopes 11 and 111. The relative position of each of the direction and the standing position of the operator 100 is calculated, and the calculated information is output to the driving direction calculation unit 34 as navigation information.
In the above configuration, when observing using the direct-view endoscope 11, the TV camera head 12 is assembled to an eyepiece (not shown) of the endoscope 11, and is inserted into the insertion portion 101 of the grip portion 10. The endoscope 11 is fixed to the grip 10 by operating a fixing knob (not shown). At this time, the projection 321 of the first guide member 32 of the endoscope 11 is inserted into the first recess 102 of the grasping unit 10 to turn on the first micro switch 30. Here, nothing is inserted into the second recess 103 of the gripping part 10, so that the second microswitch 31 is kept in the OFF state.
[0057]
On the other hand, when the oblique endoscope 111 is used, the oblique endoscope 111 is inserted into the insertion portion 101 of the grasping portion 10 and the above-described fixing knob (not shown) is operated in the same manner to grasp the grasping portion 10. To fix. At this time, the second guide member 33 has the first protrusion 331 accommodated in the first recess 102 of the grip 10 and the second protrusion 332 in the second recess 103 of the grip 10. Be contained. Here, the first and second protrusions 331 and 332 of the second guide member 33 turn on the first and second micro switches 30 and 31, and the first and second micro switches 30 and 31. The ON signal from is input to the drive direction calculator 34.
[0058]
At the same time, the first to third LED light emitting units 353, 354, and 355 are driven via a drive control unit (not shown) to emit infrared rays. Then, the infrared light emitted by the first to third LED light emitting units 353, 354, and 355 is captured as an infrared image by the digitizer 351. The digitizer 351 analyzes the detected infrared images from the first to third LED light emitting units 353, 354, and 355, and outputs the analysis information to the WS 352. The WS 352 calculates the relative position of each of the position / posture information of the housing 9, the rotation direction of the endoscope, and the standing position of the operator 100 based on each analysis information sent from the digitizer 351, and is driven as navigation information. It outputs to the direction calculating part 34.
[0059]
The drive direction calculation unit 34 detects the perspective angle of the endoscope 111 in response to the ON signals from the first and second micro switches 30 and 31, and detects the perspective angle information and the navigation information from the WS 352, Then, a control signal corresponding to the operation of the joystick switch 16 is generated and output to the motor drive unit 28. The motor drive unit 28 generates a drive signal based on the input control signal and drives the X-axis motor 211, Y-axis motor 221 and Z-axis motor 231 to control the observation field of the endoscope 111.
[0060]
Further, the drive direction calculation unit 34 generates a control signal corresponding to the navigation information from the WS 352 and the operation direction of the joystick switch 16 by performing the same navigation processing under the conditions shown in FIG. Then, the control signal is output to the motor drive unit 28. The motor drive unit 28 generates a drive signal corresponding to the control signal and drives the X-axis motor 211, the Y-axis motor 221 and the Z-axis motor 231 so that the observation visual field of the endoscope 111 corresponds to each condition. Control to the desired state.
[0061]
According to the second embodiment, by automating various setting conditions that have been manually set in the first embodiment, further handling can be simplified and the efficiency of the operation can be improved. It becomes possible to promote the reduction of time.
[0062]
(Third embodiment)
20 to 23 show a third embodiment of the present invention. The same parts as those in the first and second embodiments are denoted by the same reference numerals, and detailed description thereof is omitted.
[0063]
In other words, in the third embodiment, the imaging unit 40 is freely attached to the tip of the fourth arm 6 via the ball 8. As shown in FIG. 20, the image pickup unit 40 is provided with an image rotator 41 for image rotation adjustment on the image input side, and the image rotator 41 is rotatably attached to the other ends of the endoscopes 11 and 111. . The endoscopes 11 and 111 are not provided with, for example, an eyepiece, and an afocal beam is emitted from the other end of the objective lens (not shown) via a relay lens group.
[0064]
The photographing unit 40 includes an image rotator 41, a mirror 42, and an imaging lens 43. On the imaging surface of the imaging lens 43, a CCD 44, which is an image sensor, is moved through an X axis and a Y axis via a moving mechanism. It is provided so as to be movable in the direction. The image circle of the imaging lens 43 is larger than that of the CCD 44 and is set, for example, in a circular shape indicated by a solid line in FIG.
[0065]
The CCD 44 is fixed to an X-axis rack gear 45, for example. A pinion gear 46 is engaged with the X-axis rack gear 45, and the pinion gear 46 is fitted to the rotation shaft of the X-axis motor 47. The X-axis motor 47 is fixed to the Y-axis rack gear 48. A pinion gear 49 is engaged with the Y-axis rack gear 48, and the pinion gear 49 is fitted to the rotation shaft of the Y-axis motor 50.
[0066]
A camera control unit (CCU) 51 is connected to the CCD 44, and a TV monitor 53 is connected to the CCU 51 via an image inverting means 52.
[0067]
The X-axis motor 47 and the Y-axis motor 50 are connected to a motor drive unit 54 as shown in FIG. 22, and a drive direction calculation unit 55 is connected to the motor drive unit 54. The driving direction calculator 55 is connected to the image inverting means 52 and the joystick switch 16 of the foot switch 15.
[0068]
In the above configuration, when the surgical site is observed using the direct-view endoscope 11, the light beam incident from the objective lens of the endoscope 11 is photographed as an afocal light beam through the relay lens group (not shown). The light enters the unit 40. The light beam incident on the photographing unit 40 is incident on the triangular prism of the image rotator 41, reflected once, and then emitted toward the mirror 42. This light beam is reflected by the mirror 42 in the direction of the CCD 44 and then imaged on the imaging surface of the CCD 44 by the imaging lens 43.
[0069]
The light beam focused on the CCD 44 is converted into an electrical signal by the CCD 44, input to the CCU 51, and converted into a video signal standardized by the CCU 51. This video signal is output to the TV monitor 53 via the image inverting means 52 and displayed as an endoscopic image.
[0070]
Here, the surgeon 100 rotates the image rotator 41 using an operation knob (not shown) according to the standing position with respect to the imaging unit 40 to erect the observation image. Then, an erect image as viewed from the operator 100 is projected onto the CCD 44. Thereby, the surgeon 10 can perform an operation or the like by projecting an erect image on the TV monitor 53 by setting the image inverting means 52 to a normal image (through state that is not a mirror image). It becomes.
[0071]
In this state, when the surgeon 100 wishes to observe the upward direction, when the upward switch of the joystick switch 16 is pressed, the drive direction calculation unit 55 drives the X-axis motor 47 counterclockwise when viewed from the axial direction. The control signal to be output is output. As a result, the X-axis rack gear 45 is moved downward (X-direction) via the pinion gear 46, the CCD 44 is moved in the same direction, and the image projected on the TV monitor 53 is moved upward. .
[0072]
Similarly, when it is desired to move the observation visual field to the right, when the right direction switch of the joystick switch 16 is pressed, the drive direction calculation unit 55 outputs a control signal for driving the Y-axis motor 50 in the clockwise direction. As a result, the Y-axis rack gear 49 is moved leftward (Y + direction) via the pinion gear 49, the CCD 44 is moved leftward, and the image on the TV monitor 53 is moved rightward. That is, when the direct-view endoscope 11 is used, the actual driving direction is not corrected according to the operation direction of the joystick switch 16 from any angle.
[0073]
Next, when the surgeon 100 uses the endoscope 111 having a 90 ° perspective, the driving direction is corrected depending on whether the operator 100 observes the front direction or the front direction.
[0074]
That is, when the observation direction is the front of the operator 100, as shown in FIGS. 23A and 23B, the orientation of the image displayed on the TV monitor 53 is the actual operation of the operator's forceps and the like. Since the direction coincides with the direction, the image inverting means 52 can be set to a normal image (through state that is not a mirror image), and an upright image can be projected onto the TV monitor 53 to perform the operation. In this case, the direct-view endoscope 11 is the same, and the actual driving direction of the CCD 44 is not corrected according to the operation direction of the joystick switch 16.
[0075]
Further, when the surgeon 100 rotates the perspective endoscope 11 180 degrees in order to observe his / her front direction, the orientation of the image displayed on the TV monitor 53 is the actual surgeon's forceps and the like. The surgeon 100 can operate the image reversing means 93 to set it as a mirror image and project it on the TV monitor 53 to perform the operation. Information indicating that the image inverting means 52 has been set as a mirror image is transmitted to the drive direction calculation unit 55.
[0076]
Here, when the operator 100 wants to move the monitor image in the right direction, the right direction switch of the joystick switch 16 is pressed. Then, the drive direction calculation unit 55 outputs a control signal for driving the Y-axis motor 50 in the counterclockwise direction. As a result, the Y-axis rack gear 48 is moved to the right (Y-direction) via the pin-on gear 49, and the CCD 44 is moved to the right. Thereby, in the normal visual field, the image on the TV monitor 53 moves to the left, but since the image is set to a mirror image, the image on the TV monitor 53 is moved to the right. Thus, when the image is set as a mirror image according to the observation direction of the endoscope 11, the visual field movement direction is automatically corrected, so that the operator 100 can accurately obtain the movement direction without hesitation. The visual field can be moved.
[0077]
Therefore, the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the scope of the invention at the stage of implementation. Further, the above embodiments include inventions at various stages, and various inventions can be extracted by appropriately combining a plurality of disclosed constituent elements.
[0078]
For example, even if some constituent elements are deleted from all the constituent elements shown in the embodiment, the problems described in the column of problems to be solved by the invention can be solved, and the effects described in the effects of the invention can be obtained. In some cases, a configuration from which this configuration requirement is deleted can be extracted as an invention.
[0079]
The present invention is based on the above description.
(1) Endoscope,
An arm capable of holding the endoscope in a predetermined position in a three-dimensional space;
Driving means capable of driving the endoscope with respect to the arm;
Input means for inputting the driving direction of the endoscope;
Detecting means for detecting the viewing field direction of the endoscope;
A calculating means for calculating a driving direction of the driving means according to a detection result of the detecting means and an input state of the input means;
It is possible to provide an endoscope holding apparatus characterized by comprising:
[0080]
(2) In (1), the detection means includes first detection means for detecting a perspective angle of an endoscope;
Second detection means for detecting a rotation angle of the endoscope with respect to the drive means;
It is possible to provide an endoscope holding apparatus characterized by comprising:
[0081]
(3) In (1), photographing means for photographing an endoscopic image;
A monitor for displaying images taken by the photographing means;
Image processing means for inverting an image displayed on the monitor;
A second computing hand for computing the driving direction of the endoscope according to the state of the image processing means;
It is possible to provide an endoscope holding apparatus characterized by comprising:
[0082]
【The invention's effect】
As described above in detail, according to the present invention, it is possible to easily and easily adjust the observation visual field of an endoscope having different perspective angles, and to improve the usability. An apparatus can be provided.
[Brief description of the drawings]
FIG. 1 is a configuration diagram showing a configuration of an endoscope holding apparatus according to a first embodiment of the present invention.
2 is a block diagram showing a drive system of axes A to E constituting the joint of FIG. 1. FIG.
FIG. 3 is a perspective view showing the visual field moving mechanism of FIG.
4 is a block diagram showing an extracted control system of the visual field movement mechanism of FIG. 3;
5 is a diagram schematically showing a relationship between an observation direction setting unit in FIG. 1 and an operator's observation direction. FIG.
6 is a diagram schematically showing a relationship between an operator's observation direction and an observation visual field in FIG. 1. FIG.
7 is a diagram showing a relationship between an observation visual field and a monitor screen in FIG. 6. FIG.
FIG. 8 is a flowchart shown for explaining the observation procedure of FIG. 1;
FIG. 9 is a view for explaining the relationship among the operator's observation direction, the direct viewing endoscope movement direction, and the observation visual field direction in FIG. 1;
10 is a view for explaining the relationship among the operator's observation direction, the movement direction of the oblique endoscope, and the observation visual field direction in FIG. 1; FIG.
11 is a view for explaining the relationship between an observation direction different from FIG. 10, a movement direction of a perspective endoscope, and an observation visual field direction. FIG.
FIG. 12 is a diagram showing the relationship between the viewing angle of the endoscope, the rotation angle of the endoscope, the elements of the operator's observation direction, and the visual field movement direction on the monitor screen.
FIG. 13 is a diagram schematically showing the relationship between an endoscope with a 30 ° perspective angle and an observation field of view.
14 is a diagram showing a visual field moving direction on the monitor screen of FIG.
FIG. 15 is a view showing an extracted gripping portion of an endoscope holding apparatus according to a second embodiment of the present invention.
16 is a view showing a direct-view endoscope that is inserted into the gripping portion of FIG. 15. FIG.
17 is a view showing a perspective endoscope that is inserted into the gripping portion of FIG. 15; FIG.
18 is a block diagram showing an extracted control system of the visual field movement mechanism of FIG.
19 is a configuration diagram showing a schematic arrangement configuration of FIG. 15;
FIG. 20 is a configuration diagram showing an extracted visual field moving system of an endoscope holding apparatus according to a third embodiment of the present invention.
FIG. 21 is a view showing the visual field moving mechanism of FIG. 20;
22 is a block diagram showing a control system of the visual field movement mechanism of FIG. 21. FIG.
FIG. 23 is a diagram showing the relationship between the viewing angle of the endoscope, the rotation angle of the endoscope, the elements of the observation direction of the operator in FIG. 20, and the visual field movement direction on the monitor screen.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Stand, 2 ... Base, 3-6 ... 1st thru | or 4th arm, 8 ... Ball, 9 ... Housing, 10 ... Holding part, 101 ... Endoscope insertion hole, 102, 103 ... 1st and 2nd 11, 11, 11 a ... endoscope, 12 ... TV camera head, 13 ... CCU, 14 ... TV monitor, 15 ... foot switch part, 16 ... joystick switch, 161 ... cable, 17 ... air hose, 18 ... air Brake control circuit, 181 to 185 ... first to fourth air brakes, 19 ... solenoid valve, 20 ... switch, 21 ... X axis housing, 211 ... X axis motor, 212 ... pinion gear, 213 ... X axis rack gear, 214 ... Slit, 22 ... Y-axis housing, 221 ... Y-axis motor, 222 ... Pinion gear, 223 ... Y-axis rack gear, 224 ... Slit, 23 ... Z-axis C Zing, 231 ... Z-axis motor, 232 ... Pinion gear, 233 ... Z-axis rack gear, 234 ... Slit, 24 ... Encoder, 25 ... Drive direction calculation unit, 26 ... Endoscopic angle setting unit, 27 ... Observation direction setting unit , 28 ... motor drive unit, 100 ... surgeon, 30, 31 ... first and second microswitches, 32 ... first guide member, 321 ... projection, 33 ... second guide member, 331, 332 ... 1st and 2nd protrusion, 34 ... Drive direction calculating part, 35 ... Navigation apparatus, 351 ... Digitizer, 352 ... WS, 353, 354, 355 ... 1st thru | or 3rd LED light emission part, 40 ... Imaging unit, DESCRIPTION OF SYMBOLS 41 ... Image rotator, 42 ... Mirror, 43 ... Imaging lens, 44 ... CCD, 45 ... X-axis rack gear, 46 ... Pinion gear, 47 ... X-axis motor, 48 ... Y-axis rack gear 49 ... pinion gear, 50 ... Y-axis motor, 51 ... CCU, 52 ... image inverting means, 53 ... TV monitor, 54 ... motor driving unit, 55 ... drive direction calculating unit.

Claims (5)

A plurality of endoscopes having different field planes for observing the subject;
Holding means for holding any of the plurality of endoscopes in a three-dimensional manner so as to be movable and adjustable;
Moving means for moving the endoscope held by the holding means in three axial directions orthogonal to the holding means;
Operating means for operating the moving means to move the observation field of view of the endoscope;
According to each deflection state of the observation field of the endoscope with respect to the subject and the three-axis directions, the movement unit is driven based on the input of the operation unit while maintaining the deflection state, and the endoscope Control means for controlling movement;
An image pickup device for picking up an image of the subject observed by the endoscope, and processing and displaying the image picked up by the image pickup device, according to the observation field of view of the endoscope Imaging display means for moving the imaging device and adjusting the imaging position;
An endoscope holding apparatus comprising: The imaging display means includes
An imaging means in which the imaging element is provided so as to be movable and adjustable in two dimensions;
Moving operation means for moving the imaging means to move the observation field of view of the endoscope;
Image rotating means for rotating the image of the subject input to the imaging device of the imaging means;
Image processing means for selectively inverting the image picked up by the image pickup device of the image pickup means;
Display means for displaying the image processed by the image processing means;
The imaging element of the imaging means, and a drive control means for adjusting the two-dimensionally moved to the imaging position based on the input of the moving operation means in response to the inversion processing by the image processing means,
The endoscope holding apparatus according to claim 1, further comprising:   The observation field of view of the endoscope with respect to the subject is set based on a perspective angle of the endoscope, a rotation angle of the endoscope, and an observation direction of an operator. The endoscope holding apparatus according to the description.   The endoscope holding apparatus according to claim 3, wherein at least the perspective angle and the observation direction are manually set.   The observation field of view of the endoscope with respect to the subject is set based on perspective angle information of the endoscope, observation direction information of the operator, position information of the endoscope, and position information of the moving means. The endoscope holding apparatus according to claim 1 or 2.

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