JP2018202134A - Remote control apparatus for medical equipment - Google Patents

Abstract

To provide a remote control apparatus for medical equipment, which is able to easily change a position of a display and thereby allows an operator to freely take a desired posture even while viewing the display.SOLUTION: A remote control apparatus 100 includes: a display 3 configured to display an image captured by an endoscope 201b; a display supporting arm 4 that includes a joint 43 and supports the display 3; an electromagnetic brake 431 bringing the joint 43 into a lock state; and a trigger lever 321 releasing the lock state of the joint 43.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a remote control device for a medical instrument.

  In recent years, surgical robots have been used in various operations such as laparoscopes, and improvement in the operability of remote operation devices for surgical robots is expected. Conventionally, in order to increase an operator's immersive feeling in surgery, it is a mainstream to use a remote control device provided with a viewer that looks into the operator's face as in Patent Document 1.

International Publication No. 2016/077752

  However, although the position of the display unit can be adjusted with the remote control device of Patent Document 1, only simple adjustment such as adjusting the height, depth, and angle has been possible. Also, the operation posture could not be easily changed during the operation.

  The present invention provides a remote operation device for a medical instrument that can easily change the position of a display unit and can change an operation posture even during a long-time operation.

  A remote control device for a medical instrument according to a first aspect of the present invention includes a display unit that displays an image captured by an imaging unit, a display unit support arm that includes a joint and supports the display unit, and a grip provided on the display unit , An operation handle for remotely operating the medical instrument, a lock mechanism that locks the joint, and a release mechanism that releases the lock state of the joint, and the release mechanism is provided in the grip portion.

  A remote control device for a medical instrument according to a second aspect of the present invention includes a first display unit support arm that includes a first joint and supports a scope type display unit, and a second joint that supports a non-scope type display unit. A second display unit supporting arm, a first grip unit provided in the scope type display unit, a second grip unit provided in the non-scope type display unit, an operation handle for remotely operating the medical instrument, A first lock mechanism that locks one joint, a second lock mechanism that locks the second joint, a first release mechanism that releases the lock state of the first joint, and a lock state of the second joint that is released The first release mechanism is provided in the first gripping portion, and the second release mechanism is provided in the second gripping portion.

  According to the present invention, the operator of the remote control device can change the display unit to a free position even in a scene such as during surgery.

It is the figure which showed the outline of the remote control apparatus by 1st Embodiment. It is the perspective view which showed the remote control apparatus by 1st Embodiment. It is the figure which showed the display part support arm of the remote control device by 1st Embodiment. It is the block diagram which showed the control structure of the remote control apparatus by 1st Embodiment. It is the side view which showed the state of the 1st form of the remote control apparatus by 1st Embodiment. It is the side view which showed the state of the 2nd form of the remote control apparatus by 1st Embodiment. It is the figure which showed the model of the operator of the remote control apparatus by 1st Embodiment. It is the schematic for demonstrating the 1st example of the display part fixing mechanism and fixing release mechanism of the remote control device by 1st Embodiment. It is the schematic for demonstrating the 2nd example of the display part fixing mechanism and fixing release mechanism of the remote control device by 1st Embodiment. It is the schematic for demonstrating the 3rd example of the display part fixing mechanism and fixing release mechanism of the remote control device by 1st Embodiment. It is a perspective view which illustrates one plane in XYZ space. It is the perspective view which showed the remote control apparatus by 2nd Embodiment.

  Hereinafter, embodiments will be described with reference to the drawings.

[First Embodiment]
(Configuration of remote control device)
With reference to FIGS. 1-11, the structure of the remote control apparatus 100 by 1st Embodiment is demonstrated.

  As shown in FIG. 1, the remote control device 100 is provided to remotely control a medical instrument provided in a patient-side system 200. When an operation mode command to be executed by the patient-side system 200 is input to the remote control device 100 by the operator O who is a surgeon, the remote control device 100 sends the operation mode command to the patient via the controller 206. To the side system 200. In response to the operation mode command transmitted from the remote operation device 100, the patient-side system 200 operates a medical instrument such as a surgical instrument or an endoscope held by the surgical manipulator 201. Thereby, minimally invasive surgery is performed. The surgery support system includes a remote control device 100 and a patient side system 200 having a surgery manipulator 201. The remote operation device 100 is an example of the “medical device remote operation device” in the claims.

  The patient side system 200 constitutes an interface for performing an operation on the patient P. The patient side system 200 is arranged beside the operating table 300 on which the patient P lies. The patient-side system 200 includes a plurality of surgical manipulators 201, and one of the surgical manipulators 201 grips the endoscope 201b, and the other surgical manipulator 201 grips a surgical instrument (instrument 201a). The surgical manipulator 201 that holds the surgical instrument (instrument 201a) functions as the instrument arm 201A, and the surgical manipulator 201 that holds the endoscope 201b functions as the camera arm 201B. Each instrument arm 201A and camera arm 201B are supported in common by the platform 203. The plurality of surgical manipulators 201 have a plurality of joints, and each joint is provided with a drive unit including a servo motor and a position detector such as an encoder. The surgical manipulator 201 is configured so that a medical instrument attached to the surgical manipulator 201 is controlled to perform a desired operation by a drive signal given through the controller 206.

  The platform 203 is supported by a positioner 202 placed on the floor of the operating room. In the positioner 202, a column part 204 having a lifting shaft that can be adjusted in the vertical direction is connected to a base 205 that includes wheels and is movable on the floor surface.

  The instrument arm 201A detachably holds an instrument 201a as a medical instrument at the distal end. The instrument 201a includes a housing attached to the instrument arm 201A and an end effector provided at the distal end of an elongated shaft. Examples of the end effector include, but are not limited to, grasping forceps, scissors, hook, high-frequency knife, snare wire, clamp, and stapler, and various treatment tools can be applied. In surgery using the patient-side system 200, the instrument arm 201A is introduced into the body of the patient P via a cannula (trocar) placed on the body surface of the patient P, and the end effector of the instrument 201a is operated at the surgical site. It is arranged in the vicinity of

  An endoscope 201b (see FIG. 4) as a medical instrument is detachably attached to the tip of the camera arm 201B. The endoscope 201b captures the inside of the body cavity of the patient P, and the captured image is output to the remote operation device 100. As the endoscope 201b, a 3D endoscope or a 2D endoscope that can capture a three-dimensional image is used. In surgery using the patient-side system 200, the camera arm 201B is introduced into the body of the patient P via a trocar placed on the body surface of the patient P, and the endoscope 201b is disposed in the vicinity of the surgical site. The endoscope 201b is an example of the “imaging unit” in the claims.

  The remote operation device 100 constitutes an interface with the operator O. The remote operation device 100 is a device for the operator O to operate a medical instrument held by the surgical manipulator 201. That is, the remote control device 100 is configured to be able to transmit an operation mode command to be executed by the instrument 201a and the endoscope 201b input by the operator O to the patient side system 200 via the controller 206. . The remote control device 100 is installed beside the operating table 300 so that the state of the patient P can be seen well while operating the master, for example. The remote control device 100 can be installed in a room different from the operating room in which the operating table 300 is installed, for example, by transmitting an operation mode command wirelessly.

  The operation mode to be executed by the instrument 201a is a mode of operation realized by the operation (a series of positions and postures) of the instrument 201a and the individual functions of the instrument 201a. For example, when the instrument 201a is a grasping forceps, the operation mode to be executed by the instrument 201a is the roll rotation position and the pitch rotation position of the wrist of the end effector, and the operation of opening and closing the jaw. is there. When the instrument 201a is a high-frequency knife, the operation mode to be executed by the instrument 201a may be a vibration operation of the high-frequency knife, specifically, a current supply to the high-frequency knife. When the instrument 201a is a snare wire, the operation mode to be executed by the instrument 201a may be a binding operation and a releasing operation of the binding state. Further, it may be an operation of burning the surgical target site by supplying a current to the bipolar or monopolar.

  The operation mode to be executed by the endoscope 201b is, for example, the setting of the position and posture of the distal end of the endoscope 201b or the zoom magnification.

  The remote operation device 100 is provided with a cover 101 as shown in FIG. The cover 101 is provided so as to cover the side surface in the left-right direction (X direction), the side surface on the back surface (Y2 direction), and the top surface (surface on the Z1 direction side) of the remote control device 100. 2 and subsequent figures show the remote control device 100 with the cover 101 removed for convenience.

  As shown in FIGS. 2 and 4, the remote operation device 100 includes an operation handle 1, an operation pedal unit 2, a display unit support arm 4 that supports the display unit 3, and an armrest 5 that supports the arm of the operator O. The control device 6 and the base 7 are provided. In addition, the remote operation device 100 includes a posture operation unit 8a, an operation unit 8b, and a support mechanism 9 that supports the operation handle 1 and the armrest 5.

  The operation handle 1 is provided for remotely operating a medical instrument held by the surgical manipulator 201. Specifically, the operation handle 1 receives an operation by the operator O for operating a medical instrument (instrument 201a, endoscope 201b). A pair of operation handles 1 are provided along the X direction. That is, the X2 direction side (right side) operation handle 1 of the pair of operation handles 1 is operated by the right hand of the operator O, and the X1 direction side (left side) operation handle 1 of the pair of operation handles 1 is operated. It is operated by the left hand of the person O.

  The operation handle 1 is attached to a support portion 91 of the support mechanism 9. Further, the operation handle 1 is disposed so as to extend from the rear (Y2 direction) side of the remote operation device 100 toward the front (Y1 direction) side. A plurality of joints are provided between the support portion 91 and the operation handle 1, and the operation handle 1 can be moved with respect to the support portion 91 within a predetermined three-dimensional operation area A (see FIGS. 5 and 6). It is configured to be able to. That is, the operation handle 1 is configured to be movable in the vertical direction (Z direction), the horizontal direction (X direction), and the front-back direction (Y direction) with respect to the support portion 91. Each joint between the support unit 91 and the operation handle 1 is provided with a position detector (not shown) that detects the positional relationship of each joint. The position detection unit is, for example, an encoder, a resolver, or a potentiometer, and detects the position of the operation handle 1 with respect to the support unit 91.

  The remote operation device 100 and the patient-side system 200 constitute a master-slave type system in controlling the operation of the instrument arm 201A and the camera arm 201B. That is, the operation handle 1 constitutes a master side operation unit in a master-slave type system, and the instrument arm 201A and the camera arm 201B that hold a medical instrument constitute a slave side operation unit. When the operator O operates the operation handle 1, the movement of the operation handle 1 is caused by the tip of the instrument arm 201A (end effector of the instrument 201a) or the tip of the camera arm 201B (endoscope 201b). The operation of the instrument arm 201A or the camera arm 201B is controlled so as to trace and move.

  The patient-side system 200 is configured to control the operation of the instrument arm 201A according to the set operation magnification. For example, when the operation magnification is set to ½, the end effector of the instrument 201a is controlled to move a movement distance that is ½ of the movement distance of the operation handle 1. As a result, precise surgery can be performed accurately. The operation handle 1 is attached to the base 7 and is formed to extend in the Y direction toward the operator O.

  The operation pedal unit 2 includes a pedal that can be operated by the foot of the operator O. A specific function is assigned to each pedal, and in one function, a switching command for switching an object controlled by the operation handle 1 between the plurality of instrument arms 201A and the camera arm 201B can be input. Therefore, when it is desired to change the visual field during surgery, the operation pedal unit 2 is operated to switch the object controlled by the operation handle 1 from the instrument arm 201A to the camera arm 201B, and the operation handle 1 is operated. The endoscope 201b can be moved. After the endoscope 201b is moved, the operation pedal unit 2 is operated again, the object controlled by the operation handle 1 is returned from the camera arm 201B to the instrument arm 201A, and the operation can be continued. . The operation pedal part 2 is provided below so that it can be operated with a foot. Further, the operation pedal unit 2 is configured to be movable in the Y direction.

  In addition, in another function of the operation pedal unit 2, an operation instruction by the instrument 201a attached to the tip of the instrument arm 201A can be input. For example, the operation pedal unit 2 can input an operation for cutting or coagulating a surgical site by the instrument 201a. For example, a voltage for cutting or a voltage for coagulation is applied to the instrument 201a by operating the operation pedal unit 2.

  The display unit 3 can display an image captured by the endoscope 201b. The display unit 3 includes a scope type display unit 3a or a non-scope type display unit 3b (see FIG. 12). The scope type display unit 3a is, for example, a peeping type display unit. Further, the non-scope type display unit 3b is a concept including an open type display unit having a flat screen which is not a peeping type like a display of a normal personal computer. The scope type display unit 3 a and the non-scope type display unit 3 b are configured to be selectively attached to the remote operation device 100. In the example shown in FIG. 2, the scope type display unit 3 a is attached to the remote operation device 100. As shown in FIG. 2, the scope type display unit 3 a includes a display 31 a, a gripping unit 32, a mounting unit 33, a terminal 34 (see FIG. 4), and an angle adjustment joint 35. Further, as shown in FIG. 12, the non-scope type display unit 3b includes a display 31b, a gripping unit 32, a mounting unit 33, a terminal 34 (see FIG. 4), and an angle adjustment joint 35. The mounting portion 33 of the scope type display unit 3 a or the non-scope type display unit 3 b is configured to be attached to the mounted portion 41 of the display unit support arm 4 of the remote operation device 100. That is, the scope type display unit 3 a or the non-scope type display unit 3 b attached to the remote control device 100 is configured to be supported by the display unit support arm 4. As a result, since either an immersive remote control device or an open remote control device can be selected, the versatile remote control device 100 can be provided for the display unit 3.

  Also, because surgery usually takes several hours, the operator may feel lonely when working for a long time with an immersive remote control device. However, by switching the remote control device to the open type before or during the operation, it is possible to change to a mode in which it is easy to obtain a sense of performing the operation as a team.

  Further, a remote control device having versatility and expandability with respect to the display unit has the advantage that even if the display unit fails or is damaged, only the display unit needs to be repaired, and the entire device need not be replaced. In addition, there is an advantage that the display unit can be upgraded without replacing the entire apparatus each time a high-definition / high-quality display unit is developed. The operator also has the advantage of being able to select a display unit of a preferred manufacturer / specification (size, shape, operation panel, etc.).

  The terminal 34 is a terminal capable of transmitting video such as an SDI (serial digital interface) terminal, an analog component terminal, an HDMI (registered trademark) (high definition multimedia interface) terminal, a USB (universal serial bus) terminal, and the like. including. The terminal 34 is connected to the control device 6. That is, by connecting a connection line to the terminal 34, image information is transmitted from the control device 6 to the display unit 3. Further, the display unit 3 can be detached from the remote operation device 100 by removing the connection line from the terminal 34.

  When the scope type display unit 3a is attached, a 3D image captured by the endoscope 201b held by the camera arm 201B of the patient side system 200 is displayed. Even when the non-scope type display unit 3b is attached, a 3D image captured by the endoscope 201b provided in the patient side system 200 is displayed. When the non-scope type display unit 3b is attached, a 2D image captured by the endoscope 201b provided in the patient side system 200 may be displayed.

  The scope type display unit 3a is a viewer that the operator O looks into. The scope type display unit 3a displays an image for the right eye and an image for the left eye of the operator O, respectively. The scope type display unit 3a is, for example, a stereoscope. That is, the display 31a includes a left-eye display and a right-eye display. Also, by looking into the display 31a, the left eye cannot see the right eye display, and the right eye cannot see the left eye display. The display 31a is configured by a liquid crystal display, an organic EL display, or the like. A projection display may be used as the display 31a.

  The non-scope type display unit 3b is an open type display unit that can be seen without looking into it. The non-scope type display unit 3b is a direct view type display unit. That is, the display 31b of the non-scope type display unit 3b has a screen having a flat surface or a curved surface. For example, as the display 31b, a display having a diagonal line of 10 inches to 90 inches can be used. However, considering the balance between ensuring sufficient visibility of the operative field and being easily replaceable, the display 31b is about 15 inches to 35 inches. Is appropriate. The display 31b is configured by a liquid crystal display, an organic EL display, or the like. Further, a projection display may be used as the display 31b. Note that a known stereoscopic method such as a method using a polarizing glass or a method using an active shutter glass may be applied in order for the operator O to visually recognize an image captured by the endoscope 201b.

  The grip portion 32 is gripped when the display portion 3 is attached, detached, or moved in position. The grip portion 32 can be gripped with one hand. For example, the grip portion 32 has a handle shape, a concave shape, a convex shape, or the like. The grip portion 32 is provided on the side surface or the back surface of the display portion 3 so as not to disturb the visual recognition of the display 31a (31b). Note that the grip portion 32 can be gripped with one hand, but a plurality of grip portions 32 may be provided. For example, as shown in FIG. 2, gripping portions 32 may be provided on both sides of the display portion 3 so that an operator sitting in front can grip with either the right hand or the left hand. The grip portion 32 is provided with a trigger lever 321. The trigger lever 321 is an example of the “release mechanism” in the claims.

  The mounting portion 33 is attached to the mounted portion 41 of the display unit support arm 4. That is, the attached portion 41 is attached so that the scope-type display portion 3a and the non-scope-type display portion 3b can be selectively attached and detached. For example, the mounting portion 33 includes an engaging portion 331 as in the first example shown in FIG. The mounted portion 41 includes a fixing release button 411 and an engaging portion 412. As shown in FIG. 8A, in the fixed state, the engaging portion 331 of the mounting portion 33 and the engaging portion 412 of the mounted portion 41 are engaged, and the mounted portion 41 of the display unit support arm 4 is engaged. On the other hand, the mounting portion 33 is fixed. Thereby, the display unit 3 is fixed and supported by the display unit support arm 4. That is, the engaging portion 331 and the engaging portion 412 constitute a display portion fixing mechanism for fixing the display portion 3 (scope type display portion 3a or non-scope type display portion 3b).

  As shown in FIG. 8B, when the fixation release button 411 is pressed downward, the engaging portion 412 moves, and the engagement between the engaging portion 331 and the engaging portion 412 is released. Thereby, the fixed state (locked state) of the mounting portion 33 with respect to the mounted portion 41 is released. That is, the fixing release button 411 functions as a fixing release mechanism that releases the fixed state by the display unit fixing mechanism configured by the engaging portion 331 and the engaging portion 412. Further, the fixing release mechanism is configured to release the fixing state by the display unit fixing mechanism by the action of a downward force in the vertical direction. Thereby, the fixing state by the display unit fixing mechanism can be easily released by the fixing release mechanism.

  As shown in FIG. 8C, the display unit 3 is detached from the remote control device 100 by causing the grip portion 32 of the display unit 3 to act on the upper side in the vertical direction during the action of the unlocking mechanism on the lower side in the vertical direction. It is. As a result, the display unit 3 can be removed while exerting forces in the opposite directions of the release operation in the lower vertical direction and the lifting of the operation unit in the upper vertical direction, so that the display unit 3 can be stably and safely removed. it can. Since the display unit 3 can be detached from the display unit support arm 4 in the upward direction, the display unit 3 can be removed without interfering with the operation handle 1 positioned below.

  The display unit fixing mechanism and the fixing release mechanism may have other configurations. For example, the second example shown in FIG. 9 may be used. The mounting part 33 includes an engaging part 332 as in the second example shown in FIG. The mounted portion 41 includes an engaging portion 413. As shown in FIG. 9A, in the fixed state, the engaging portion 332 of the mounting portion 33 and the engaging portion 413 of the mounted portion 41 are engaged, and the mounted portion 41 of the display unit support arm 4 is engaged. On the other hand, the mounting portion 33 is fixed. Specifically, the engaging portion 332 sandwiches and engages the engaging portion 413 to engage. Thereby, the display unit 3 is fixed and supported by the display unit support arm 4. That is, the engaging portion 332 and the engaging portion 413 constitute a display portion fixing mechanism for fixing the display portion 3 (scope type display portion 3a or non-scope type display portion 3b).

  As shown in FIG. 9B, when the engaging portion 332 is pressed from both sides, the pinching by the engaging portion 332 is released, and the engagement between the engaging portion 332 and the engaging portion 413 is released. The fixed state (locked state) of the mounting portion 33 with respect to the mounted portion 41 is released. As shown in FIG. 9C, the display unit 3 is detached from the remote control device 100 by causing the gripping unit 32 of the display unit 3 to act on the upper side in the vertical direction when the fixed state is released.

  The display unit fixing mechanism and the fixing release mechanism may have other configurations. For example, a third example shown in FIG. 10 may be used. The mounting portion 33 includes a notch 333 as in the third example shown in FIG. The mounted portion 41 includes a fixing release button 414, a fitting portion 415, and an engaging portion 416. As shown in FIG. 10A, the fixing release button 414 is urged vertically upward by a spring or the like, and the engaging portion 416 is urged away from the fitting portion 415 in the horizontal direction. The movement in the vertical direction and the movement in the horizontal direction of the engaging portion 416 are mechanisms that move in conjunction with each other by a gear or the like.

  In the fixed state, the notch 333 of the mounting portion 33 and the engaging portion 416 of the mounted portion 41 are engaged, and the mounting portion 33 is fixed to the mounted portion 41 of the display unit support arm 4. Thereby, the display unit 3 is fixed and supported by the display unit support arm 4. That is, the notch 333 and the engaging part 416 constitute a display part fixing mechanism for fixing the display part 3 (scope type display part 3a or non-scope type display part 3b).

  As shown in FIG. 10B, when the fixing release button 414 is pressed downward, the fitting portion 415 moves downward. In conjunction with this, the engaging portion 416 moves in a direction approaching the fitting portion 415, and the engaging portion 416 is fitted into the fitting portion 415. Thereby, the engagement between the notch 333 and the engaging portion 416 is released. As a result, the fixed state (locked state) of the mounting portion 33 with respect to the mounted portion 41 is released. That is, the fixing release button 414 functions as a fixing release mechanism that releases the fixing state by the display unit fixing mechanism including the notch 333 and the engaging portion 416. Further, the fixing release mechanism is configured to release the fixing state by the display unit fixing mechanism by the action of a downward force in the vertical direction.

  As shown in FIG. 10C, the display unit 3 is detached from the remote control device 100 by causing the grip portion 32 of the display unit 3 to act on the upper side in the vertical direction when the fixed state is released.

  Since the engaging part 416 has an inclined surface whose lower dimension is larger than the upper dimension, when the attaching part 33 is pushed downward in the vertical direction with respect to the attached part 41, the attaching part 33 is engaged. When the engaging portion 416 is pushed toward the fitting portion 415 in the horizontal direction by contacting the inclined surface of the portion 416 and moved to a predetermined position, the engaging portion 416 is fitted into the notch 333 and locked. .

  As shown in FIG. 2, the display unit support arm 4 is configured to support the display unit 3. The display unit support arm 4 includes a mounted portion 41, an arm portion 42, a plurality of joints 43, and a parallel link mechanism 44. The display unit support arm 4 is provided with a mounted portion 41 at one end and is supported by a column 45 at the other end. The column 45 is fixed to the support portion 91 of the support mechanism 9. That is, the display unit 3 is supported by the support unit 91. The display unit support arm 4 is configured to be rotatable about vertical rotation axes A1, A2, and A3. Further, the display unit support arm 4 is configured to be able to move the mounted portion 41 in the vertical direction by the parallel link mechanism 44. That is, the mounted portion 41 is supported by the display unit support arm 4 with four degrees of freedom.

  The display unit support arm 4 includes, as the joint 43, a joint 43a, a joint 43b, and a joint 43c. The joints 43a, 43b and 43c are provided with electromagnetic brakes 431a, 431b and 431c, respectively, as the electromagnetic brake 431. The parallel link mechanism 44 is provided with an electromagnetic brake 441 a as the electromagnetic brake 441. The joints 43a, 43b, 43c and the parallel link mechanism 44 are examples of the “joint” in the claims, and the electromagnetic brakes 431a, 431b, 431c and 441a are examples of the “lock mechanism” in the claims. It is.

  As shown in FIG. 2, a scope type display unit 3 a is attached to the display unit support arm 4. That is, the display unit support arm 4 supports the scope type display unit 3a.

  The joint 43a connects the mounted portion 41 and the third link 48 so as to be rotatable about the rotation axis A3. The joint 43b connects the second link 47 and the first link 46 so as to be rotatable about the rotation axis A2. The joint 43c connects the first link 46 and the column 45 so as to be rotatable about the rotation axis A1. As shown in FIG. 3, the parallel link mechanism 44 is capable of rotating the third link 48 and the second link 47 in the B1 direction around the rotation axis in the horizontal direction perpendicular to the rotation axes A1 to A3. Connected.

  The electromagnetic brake 431 is configured to bring the joint 43 into a locked state. Specifically, when the electromagnetic brake 431 is not energized, the operation of the joint 43 is prevented by pressing at least one of the two links connected on the rotating shaft, and is brought into a locked state. Further, when the electromagnetic brake 431 is energized, a magnetic force is generated in the coil of the electromagnet and the brake that presses the first link 46 is released to release the joint 43 from the locked state. The electromagnetic brake 431a puts the joint 43a in a locked state by pressing the mounted portion 41 on the rotation axis A3. The electromagnetic brake 431b presses the second link 47 on the rotation axis A2, thereby bringing the joint 43b into a locked state. The electromagnetic brake 431c presses the first link 46 on the rotation axis A1, thereby bringing the joint 43c into a locked state.

  The electromagnetic brake 441a is configured to bring the parallel link mechanism 44 into a locked state. Specifically, the electromagnetic brake 441a is brought into a locked state by pressing the parallel link mechanism 44 when not energized. Further, the electromagnetic brake 441a releases the locked state of the parallel link mechanism 44 when energized.

  The grip portion 32 of the display unit 3 is provided with a trigger lever 321 as a release mechanism for releasing the lock state of the electromagnetic brakes 431 and 441. When the trigger lever 321 is pressed, the corresponding electromagnetic brakes 431 and 441 are energized, and the locked state is released. When the trigger lever 321 is operated by the operator O, the corresponding joint (at least one of the joints 43a to 43c and the parallel link mechanism 44) is unlocked.

  In the present embodiment, as an example, two trigger levers 321 are provided, one on each side of the display unit 3. As shown in FIG. 2, one trigger lever 321a is provided on each side of the scope type display unit 3a. Further, as shown in FIG. 12, one trigger lever 321b is provided on each of the left and right sides of the non-scope type display unit 3b. The trigger lever 321 is released by being grasped (pressing operation) together with the grip portion 32. When both the left and right trigger levers 321 are pressed, all the joints (the joints 43a to 43c and the parallel link mechanism 44) are unlocked, and neither the left or right trigger lever 321 is pressed. In the case of pressing only, the locked state of any joint is not released. With such a configuration, even when one trigger lever 321 is unintentionally touched and a release operation is performed, the locked state is not released, so that the joint 43 and the parallel link mechanism 44 are unintentionally locked. It is possible to suppress the release.

  As a result, in a state where both the left and right trigger levers 321 are not pressed, all the joints of the display unit support arm 4 can be locked, so that the position of the display unit 3 is prevented from being displaced during the operation of the operation handle 1. can do. On the other hand, when the operation of the operation handle 1 is interrupted and both the left and right trigger levers 321 are pressed, the operator O unlocks the display unit 3 by unlocking all joints of the display unit support arm 4. Since the position can be arbitrarily changed, the display unit 3 can be easily changed to an arbitrary position. Since the display unit 3 is supported by the display unit support arm 4 configured by a plurality of joints and links as described above, the display unit angle adjustment, the height direction adjustment, and the depth direction as in Patent Document 1 are merely performed. Compared to a mechanism capable of adjustment, the display unit 3 has a wider adjustment range, and the display unit 3 can be moved linearly to an arbitrary place. Even when the scope type display unit 3a of the type that looks into the display unit 3 is used, the scope type display unit 3a can be arbitrarily selected by pressing both the left and right trigger levers 321 while looking into the scope type display unit 3a. Since the angle, height, and depth of the display unit 3 are individually set, the operation posture can be changed sensuously and quickly compared to the case where the operation posture is confirmed by filling the face. can do.

  As described above, the operation posture can be changed easily and over a wide adjustment range even during a long-running operation, reducing the fatigue on the operator and the adverse health effects caused by continuing the same posture. it can.

  The display unit support arm 4 is disposed on the side opposite to the operator O with respect to the display unit 3. That is, the display unit support arm 4 is disposed on the rear side (Y2 direction side) with respect to the display unit 3. Thereby, since it can suppress that the display part support arm 4 and the operator O interfere, the freedom degree of the movement of the display part support arm 4 can be raised effectively.

  As shown in FIG. 3, the parallel link mechanism 44 includes an electromagnetic brake 441, links 442 a and 442 b, pivots 443 a, 443 b, 443 c, and 443 d, a spring 444, and a base end 445. The parallel link mechanism 44 is configured to translate the display unit 3 mounted on the mounted unit 41 in the vertical direction. That is, the parallel link mechanism 44 is configured to move the display unit 3 in the vertical direction without changing the angle of the display surface of the display unit 3.

  Specifically, in the parallel link mechanism 44, the link 442a is rotatably connected to the pivots 443a and 443d. The link 442b is pivotally connected to the pivots 443b and 443c. The links 442a and 442b are arranged in parallel to each other. The pivots 443a and 443b are arranged side by side in the vertical direction at a predetermined interval on a straight line parallel to the vertical direction. The pivots 443c and 443d are arranged side by side in the vertical direction at a predetermined interval on a straight line parallel to the vertical direction. That is, each of the pivots 443a to 443d is arranged at the apex of the parallelogram. In other words, the line connecting the pivots 443a and 443b and the line connecting the pivots 443d and 443c are parallel to each other. Thereby, the line connecting the pivot 443d and the pivot 443c is always parallel to the vertical direction. Thereby, when the to-be-attached part 41 is moved to an up-down direction, the angle of an up-down direction is kept the same. However, when the mounted portion 41 is moved in the vertical direction by the parallel link mechanism 44, the horizontal position of the mounted portion 41 is slightly displaced.

  The electromagnetic brake 441 is attached to the pivot 443a. That is, the electromagnetic brake 441 is configured to lock the pivot of the pivot 443a by pressing the second link 47 and the parallel link mechanism 44. When the pivot of the pivot 443a is locked, the pivots of the pivots 443b to 443d are also locked because they are connected by the links 442a and 442b.

  The spring 444 is provided so as to press the proximal end portion 445 of the second link 47 having a shape protruding in an arc shape. When the end of the spring 444 on the second link 47 side presses the arcuate base end 445, the end of the spring 444 attempts to move upward along the arcuate base end 445. A force is applied to turn the end of the parallel link mechanism 44 opposite to the second link 47 upward. Thereby, even when the display unit 3 has to be moved against gravity, the operator O can easily move it upward.

  Separately from the joint 43 and the parallel link mechanism 44 of the display unit support arm 4, an angle adjustment joint 35 that adjusts the angle of the display surface of the display unit 3 is provided between the display unit support arm 4 and the display unit 3. ing. The angle adjustment joint 35a supports the scope type display unit 3a so as to be rotatable in the C1 direction (see FIG. 2). The angle adjustment joint 35b supports the non-scope type display unit 3b so as to be rotatable in the C2 direction (see FIG. 12). The angle adjustment joint 35 is arranged on the display unit 3 side when the display unit 3 is detached from the display unit support arm 4. Thereby, since the angle of the display surface of the display part 3 can be changed independently, the angle of the display surface of the display part 3 can be adjusted easily.

  Note that the display unit support arm 4 may be manually changed in posture by the operator O or another person, or provided with a position detector such as a motor or an encoder, and a drive unit including a brake to control the operation. The posture may be changed. Even in this case, the display unit support arm 4 can be moved manually, and can also be moved electrically. When the display unit 3 is moved manually, when the brake is released, the motor moves in accordance with the manual movement, and the position can be stored by the position detector. Further, when the display unit is moved electrically, the operation may be instructed with a handheld device. The handheld may be provided with a release button for releasing the brake, or the brake may be automatically released by operating the movement direction instruction button. The handheld may be constituted by a remote control having a plurality of buttons, for example. Moreover, you may comprise a handheld by a teaching pendant. Further, the position of the display unit 3 (the posture of the display unit support arm 4) may be stored for each operator. Further, when the standing position / sitting position is changed, the position of the display unit 3 (the posture of the display unit support arm 4) may be changed in conjunction.

  The armrest 5 is configured to support the arm of the operator O. The armrest 5 includes an arm support part 51, a pair of connection parts 52, and an operation part 53. The arm support portion 51 is disposed on the front side (Y1 direction side) of the operation handle 1 and is configured to support the arm of the operator O. Thereby, since the arm of the operator O can be stabilized, the operation of the operation handle 1 by the operator O can be performed stably. That is, even when the end effector is moved finely, the operator O can perform the operation while stabilizing the armrest 5 by leaning the armrest 5 on the elbow or the like. Further, even when the operation takes a long time, the burden on the operator O can be reduced. The arm support portion 51 is formed to extend in the X direction. A pair of connection parts 52 are provided. The pair of connection parts 52 are respectively provided at both ends of the arm support part 51 so as to sandwich the arm support part 51 in the X direction. The connection part 52 is configured to support the arm support part 51. Moreover, the connection part 52 is formed so that it may extend in a Y direction. That is, the connection part 52 is connected to the arm support part 51 at the end in the Y1 direction. Further, the end portion in the Y2 direction of the connection portion 52 is connected to the support portion 91 of the support mechanism 9. That is, the armrest 5 is supported by the support mechanism 9. Moreover, as shown in FIG. 2, the connection part 52 may be formed so that it may extend below along the near side (Y1 direction side) from the back side (Y2 direction side). Further, as shown in FIGS. 5 and 6, the connecting portion 52 may be formed so as to extend upward along the front side (Y1 direction side) from the back side (Y2 direction side). Moreover, the connection part 52 may be formed so that it may extend along a horizontal direction. The operation unit 53 can operate the setting of the remote operation device 100. For example, it is possible to operate the attitude of the remote operation device 100 with the operation unit 53. In this case, the operation unit 53 functions as the posture operation unit 8a. The operation unit 53 may function as the operation unit 8b. The operation unit 53 includes, for example, a touch panel.

  As shown in FIG. 4, the control device 6 includes, for example, a control unit 61 having an arithmetic unit such as a CPU, a storage unit 62 having a memory such as a ROM and a RAM, and an image control unit 63. The control device 6 may be configured by a single control device that performs centralized control, or may be configured by a plurality of control devices that perform distributed control in cooperation with each other. The control unit 61 determines whether the operation mode command input from the operation handle 1 is an operation mode command to be executed by the instrument arm 201A according to the switching state of the operation pedal unit 2, or the endoscope. It is determined whether it is an operation mode command to be executed by 201b. When the controller 61 determines that the operation mode command input to the operation handle 1 is an operation mode command to be executed by the instrument 201a, the control unit 61 transmits the operation mode command to the instrument arm 201A. . As a result, the instrument arm 201A is driven, and the operation of the instrument 201a attached to the instrument arm 201A is controlled by this driving.

  If the controller 61 determines that the motion mode command input to the operation handle 1 is a motion mode command to be executed by the endoscope 201b, the control unit 61 transmits the motion mode command to the camera arm 201B. Accordingly, the camera arm 201B is driven, and the operation of the endoscope 201b attached to the camera arm 201B is controlled by this driving.

  For example, a control program corresponding to the type of the instrument 201a is stored in the storage unit 62, and the control unit 61 reads out the control program according to the type of the attached instrument 201a, thereby enabling remote operation. The operation command of the operation handle 1 and / or the operation pedal unit 2 of the device 100 can be operated in accordance with the individual instrument 201a.

  The image control unit 63 transmits the image acquired by the endoscope 201 b to the terminal 34 of the display unit 3. The image control unit 63 performs image processing correction processing as necessary.

  The posture operation unit 8 a is configured to receive an operation for moving the operation handle 1, the display unit 3 supported by the display unit support arm 4, and the armrest 5 up and down. In addition, the posture operation unit 8a is configured to receive an operation for deforming the remote operation device 100 between the first posture and the second posture.

  That is, the posture operation unit 8a is an operation unit that can input a posture change command for changing the posture of the remote operation device 100 between the standing position (first posture) and the sitting position (second posture). The posture operation unit 8a has a plurality of operation buttons.

  The support mechanism 9 includes a support part 91 and a drive part 92. The support portion 91 supports the operation handle 1 and the armrest 5. In addition, the support unit 91 supports the display unit 3 via the display unit support arm 4. The drive unit 92 is configured to move the support unit 91 in the vertical direction. Specifically, the drive unit 92 includes, for example, a motor and an encoder, and moves the support unit 91 in the vertical direction under the control of the control unit 61. The support mechanism 9 may be manually changed in posture by the operator O or another person. Further, the drive unit 92 of the support mechanism 9 may be driven by air pressure or hydraulic pressure. Further, the position of the armrest 5 may be adjusted by rotating with respect to the support mechanism 9. For example, the armrest 5 may rotate around a rotation axis along the X direction.

  For example, the support mechanism 9 holds the operation handle 1 by positioning the operation handle 1 located at the neutral position A0 of the operation area A at a height position H1 of 85 cm or more from the floor surface on which the remote operation device 100 is installed. The operation handle 1 positioned at the neutral position A0 of the operation area A is positioned at a height position H2 that is 48 cm or more lower than the height position H1 (see FIG. 5), and the operation handle 1 is held. It is configured to be able to transition between the second mode (see FIG. 6). Accordingly, the operation handle 1 can be operated while the operator O is standing by positioning the operation handle 1 positioned at the neutral position A0 of the operation area A at a height position H1 of 85 cm or more from the floor surface. it can. Further, by positioning the operation handle 1 located at the neutral position A0 of the operation area A at a height position H2 that is 48 cm or more lower than the height position H1, the operation handle 1 is operated while the operator O is sitting. be able to. Accordingly, the operator O can operate the remote operation device 100 in a desired posture. Further, since the operation handle 1 is supported by the support mechanism 9, it is not necessary for the operator O to support the operation handle 1. Thereby, it can suppress that the burden of the operator O increases. Further, the arm rest 5 that supports the arm of the operator O can further reduce the burden on the operator O and can stabilize the arm of the operator O, so that the operator O can operate the operation handle 1. It can be performed stably.

  The support mechanism 9 is a first form for holding the operation handle 1 so that the operation area A of the operation handle 1 is within a clean area set to a predetermined height or more from the floor surface on which the remote operation device 100 is installed. Transition between (see FIG. 5) and a second configuration (see FIG. 6) in which the operation handle 1 is held such that at least a part of the operation area A of the operation handle 1 is located in an area below the clean area. It is configured to be possible.

  Here, in the operating room, a clean operation is performed in order to prevent the part opened by surgery and the medical device from being contaminated by pathogenic bacteria or foreign substances. In this clean operation, a clean area and a contaminated area other than the clean area are set. And, the area from the floor surface where there is a high possibility that foreign matter such as dust or dust has fallen to a certain height H is treated as a contaminated area, and is excluded from the clean area. This area is, for example, an area from the floor surface to a height of about 70 cm. That is, for example, an area having a height of about 70 cm or more from the floor surface on which the remote control device 100 is installed is set as the clean area. Members of the surgical team, including operator O, should consider that only objects that have been sterilized are located in the clean area during the operation, and move objects located in the contaminated area to the clean area. Sterilize the object. Similarly, when a member of the surgical team, including operator O, places his hand in a contaminated area, the hand is sterilized prior to direct contact with an object located in the clean area. Note that the operation handle 1 is handled as being not clean, and even if it is in a clean area, if the sterilization process or drape is not performed, the operator O does not access the patient P while operating the operation handle 1. .

  As a result, the operator O puts his hand out of the clean area by positioning the operation handle 1 so that the operation area A of the operation handle 1 is within the clean area set to a predetermined height or more from the floor surface. The operation handle 1 can be operated. Thereby, for example, if the operation handle 1 is processed cleanly, the hand of the operator O can be kept clean. Further, by holding the operation handle 1 so that at least a part of the operation area A of the operation handle 1 is located in an area below the clean area, the operation handle 1 can be moved at a low position where the operator O is sitting. Can be operated. Accordingly, the operator O can operate the remote operation device 100 in a desired posture. Further, since the operation handle 1 is supported by the support mechanism 9, it is not necessary for the operator O to support the operation handle 1. Thereby, it can suppress that the burden of the operator O increases.

  Further, the support mechanism 9 includes a first form (see FIG. 5) in which the operation handle 1 is held in a position suitable for the operator O to operate the operation handle 1 in a standing position, and the operation handle 1 is held by the operator O. It is configured to be able to transition between a second form (see FIG. 6) in which the operation handle 1 is held at a position adapted to be operated in the sitting position. Thereby, the operation handle 1 can be operated in the state where the operator O stood by making the remote control device 100 into the first form. In addition, by making the remote control device 100 in the second form, the operation handle 1 can be operated while the operator O is sitting. Accordingly, the operator O can operate the remote operation device 100 in a desired posture. Further, since the operation handle 1 is supported by the support mechanism 9, it is not necessary for the operator O to support the operation handle 1. Thereby, it can suppress that the burden of the operator O increases.

  Moreover, the support mechanism 9 is comprised so that both the operation handle 1 and the armrest 5 can move to an up-down direction between a 1st form and a 2nd form. Specifically, the support mechanism 9 is configured to be able to move both the operation handle 1 and the armrest 5 integrally in the vertical direction between the first form and the second form. Thereby, compared with the case where the member for moving the operation handle 1 and the armrest 5 to an up-down direction is provided separately, since a number of parts can be reduced, while being able to simplify an apparatus structure, An increase in the size of the apparatus can be suppressed. Further, the support mechanism 9 is configured so that the display unit 3 supported by the display unit support arm 4 can also move in the vertical direction between the first mode and the second mode. That is, the support mechanism 9 is configured to be able to move the operation handle 1, the armrest 5, and the display unit 3 integrally in the vertical direction between the first form and the second form.

  In other words, the support mechanism 9 supports the display unit 3 that displays an image captured by the endoscope 201b, and the relative position of the display unit 3 with respect to the operation handle 1 in each of the first form and the second form. The display unit 3 is supported so that it can be changed. Specifically, the position of the display unit 3 is moved relative to the operation handle 1 by the display unit support arm 4 supported by the support mechanism 9. Thereby, since the position of the display part 3 with respect to the operation handle 1 can be changed according to the physique and posture of the operator O, versatility regarding the display part 3 can be enhanced.

  Further, when the form is deformed between the first form and the second form, the operation of the patient-side system 200 by the operation handle 1 is invalidated. Specifically, when the form is changed between the first form and the second form, the operation by the operation handle 1 is invalidated or the transmission of the operation mode command is invalidated. Has been. That is, the control unit 61 does not transmit an operation mode command to the patient-side system 200 even when a command is transmitted from the operation handle 1 when the mode is deformed between the first mode and the second mode. . Thereby, it can suppress that the operation handle 1 is operated unintentionally and the patient side system 200 operate | moves in the middle of changing a form between the 1st form and the 2nd form.

  As shown in FIG. 5, when the remote control device 100 is in the standing position (first position), the operating handle 1 is positioned at the neutral position A0 with the arm O bent in a substantially right angle. The operation handle 1 is set so as to be positioned at a height suitable for gripping. Moreover, it is set so that the display unit 3 is positioned at a height position suitable for the operator O in a standing state to visually recognize the display unit 3. For example, when the scope type display unit 3a is attached, the scope type display unit 3a is set so as to be at the eye height of the operator O.

  In an operating room, when an area from the floor surface to a height H of 70 cm is set as a contaminated area, if the design is based on a human model in ergonomics, the operation handle is in the standing adaptive form (first posture). One operation area A can be configured so as to be entirely contained in a clean area of 70 cm or more from the floor surface.

  When the remote operation device 100 is in the standing position (first posture), the operation pedal unit 2 is moved to the position P1 on the near side (Y1 direction side) of the remote operation device 100. That is, the operating pedal unit 2 is moved to a position where the foot reaches the operating pedal unit 2 in a state where the standing operator O touches the operating handle 1.

  As shown in FIG. 6, when the posture of the remote control device 100 is the sitting position (second posture), the operator O sitting in the chair is positioned at the neutral position A0 with his arm bent at a substantially right angle. The operation handle 1 is set so as to be positioned at a height position suitable for gripping the handle 1. In addition, the display unit 3 is set at a height suitable for the operator O sitting in a chair to view the display unit 3. For example, when the scope type display unit 3a is attached, the scope type display unit 3a is set so as to be at the eye height of the operator O. In the operation for a long time, the operator O can reduce the accumulation of fatigue of the operator O by performing the operation in the sitting position.

  In the operating room, when an area from the floor surface to a height H of 70 cm is set as a contaminated area, the operating handle 1 is set in the sitting position adaptation mode (second posture) when designed based on a human model in ergonomics. At least a part of the operation area A is located in the contaminated area.

  When the remote operation device 100 is in the sitting position (second posture), the operation pedal unit 2 is moved to the position P2 on the rear side (Y2 direction side) of the remote operation device 100. That is, when the operator O sitting on the chair touches the operation handle 1, the operation pedal unit 2 is moved to a position where the foot can reach the operation pedal unit 2. For example, the operation pedal unit 2 is configured to be able to move 300 mm or more in the front-rear direction (Y direction). Preferably, the operation pedal portion 2 is configured to be able to move 350 mm or more in the front-rear direction (Y direction). Thereby, the operation pedal part 2 can be easily moved to a position suitable for each of the first posture and the second posture.

  In order to specifically design the dimensions and the like of the remote control device 100, measurement data described in “1988 ANTHROPOMETRIC SURVEY OF US ARMY PERSONNEL: METHODS AND SUMMARY STATISTICS (1988)” was used.

  The JIS standard can be referred to for designing the remote control device 100. For example, “JIS Z8503-4: 2006 (ISO 11064-4: 2004) Ergonomics—Control Center Design—Part 4: Workstation "Placement and dimensions" specifies the use of human models of the 5th and 95th percentile.

  The operation area A is defined as 15 cm above and below the neutral position A0, that is, the height dimension of the operation area A is defined as 30 cm. This is defined on the basis of the dimension in the height direction of the operation region of the surgical instrument and the operation magnification of the operation handle 1 set in order to keep the operability of the surgical instrument favorable during laparoscopic surgery. The dimension of the operation region of the set surgical tool in the height direction is 30 cm, and the operation magnification of the operation handle 1 is ½. Therefore, the dimension in the height direction of the operation area A derived based on the dimension in the height direction of the operation area of the surgical instrument and the operation magnification of the operation handle 1 is 30 cm.

  FIG. 7A is a diagram showing a model of the operator O, and is a diagram showing a model of the large operator O1. FIG. 7B is a diagram illustrating a model of the operator O, and is a diagram illustrating a model of the small operator O2.

  As shown in FIG. 7A, German male body data was used as a model for a large operator O1. Of the 100 randomly selected German male models, with the fifth model from the top standing up (standing position), the arm is bent at a right angle and the operation handle 1 positioned at the neutral position A0 in the operation area A is held. In this case, the height position of the operation handle 1 is about 1176 mm, the lower limit of the height position of the operation area A is about 1026 mm, and the upper limit is about 1326 mm. On the other hand, the height position of the operation handle 1 when the arm is bent at a right angle and the operation handle 1 positioned at the neutral position A0 of the operation area A is gripped is about 703 mm. The lower limit is about 553 mm, and the upper limit is about 853 mm.

  As shown in FIG. 7B, Japanese female body data was used as a model of the small operator O2. Operation when grasping the operation handle 1 positioned at the neutral position A0 of the operation area A with the arm bent at a right angle with the fifth model from the bottom standing up out of 100 randomly selected Japanese female models The height position of the handle 1 is about 992 mm, the lower limit of the height position of the operation area A is about 842 mm, and the upper limit is about 1142 mm. On the other hand, the height position of the operation handle 1 when the arm is bent at a right angle and the operation handle 1 positioned at the neutral position A0 of the operation area A is gripped is about 643 mm, and the height position of the operation area A is The lower limit is about 493 mm, and the upper limit is about 793 mm.

  Based on the above data, the height position of the operation handle 1 at which a plurality of operators O having different physiques can take a standing posture and a sitting posture without problems is as follows. First, the height position of the operation handle 1 positioned at the neutral position A0 of the operation area A in the standing position adaptation mode (first mode) is set to about 99 cm or more corresponding to the model of the small operator O2 in the standing position. It is preferable. As a result, most operators O can comfortably operate the operation handle 1 while standing. In this case, in the operation handle 1 configured to be able to move downward by 15 cm from the neutral position A0, the lower limit of the height position of the operation region A of the operation handle 1 in the standing position adaptation mode is 84 cm or more as described above. It is.

  Moreover, it is preferable to set the height position of the operation handle 1 located at the neutral position A0 in the standing position adaptation mode (first state) to 85 cm or more. Accordingly, in the operation handle 1 configured to be able to move downward by 15 cm from the neutral position A0, the lower limit of the height position of the operation region A of the operation handle 1 in the standing position adaptation mode is 70 cm or more. One operation area A can be stored in a clean area. Further, as described above, since the lower limit of the height position of the operation area A corresponding to the model of the standing operator O2 is about 84 cm, the lower limit of the height position of the operation area A is set to 70 cm. Thus, a large number of operators O having a physique difference can comfortably operate the operation handle 1 in a standing position.

  Next, the height position of the operation handle 1 located at the neutral position A0 of the operation area A in the sitting position adaptation mode (second state) is set to about 64 cm or more corresponding to the model of the small operator O2 in the sitting position. Is preferred. As a result, most operators O can comfortably operate the operation handle 1 in the sitting position.

  Next, the displacement (adjustment width) of the height of the operation handle 1 when the remote operation device 100 is changed between the standing adaptive configuration and the sitting adaptive configuration is a model of the small operator O2 standing. The difference between the height position of the operation handle 1 positioned at the neutral position A0 corresponding to the height of approximately 99 cm and the height position of the operation handle 1 positioned at the neutral position A0 corresponding to the model of the small operator O2 in the sitting position is It is preferable to secure a certain length of about 35 cm or more.

  Further, the displacement of the height position of the operation handle 1 when the remote control device 100 is changed between the standing position adaptive form and the sitting position adapted form is a neutral position corresponding to the model of the operator O1 who is standing upright. A large operator O1 in a sitting position with a height position of about 118 cm (in this model, the height position of the operating handle 1 that is positioned at the neutral position A0 in the standing position adaptation mode is maximum) in the position A0. It is preferable to secure about 48 cm or more which is a difference from the height position of about 70 cm of the operation handle 1 located at the neutral position A0 corresponding to the model.

  Thus, the adjustment width of the height position of the operation handle 1 when transiting between the standing adaptive form and the sitting adaptive form is ensured in order to match the physique of the operator O in the standing adaptive form. It is desirable to set an adjustment width (for example, the height position of the operation handle 1 positioned at the neutral position A0 corresponding to the model of the large operator O1 and the operation positioned at the neutral position A0 corresponding to the model of the small operator O2). It corresponds to the adjustment range (for example, a model of a large operator O1) that should be secured in order to match the physique of the operator O in the sitting position adaptation mode (about 19 cm of the difference from the height position of the handle 1) This is larger than the difference between the height position of the operation handle 1 located at the neutral position A0 and the height position of the operation handle 1 located at the neutral position A0 corresponding to the model of the small operator O2.

  When the position of the operation handle 1 is set to be higher than the height position of about 118 cm of the operation handle 1 located at the neutral position A0 corresponding to the model of the large operator O1 in the standing position, this adjustment range is further increased. It will be expanded. And it is preferable to ensure 50 cm or more from the height position of the position of the operation handle 1 in the standing position adaptation mode. Further, the displacement of the height position of the operation handle 1 when the remote operation device 100 is transitioned between the standing adaptive configuration and the sitting adaptive configuration is a neutral position corresponding to the model of the operator O1 who is standing upright. More than about 54 cm, which is the difference between the height position of about 118 cm of the operation handle 1 located at A0 and the height position of about 64 cm of the operation handle 1 located at the neutral position A0 corresponding to the model of the small operator O2 in the sitting position. It is preferable to ensure. Regarding the definition of the operation area A, the vertical width is assumed to be 30 cm this time, but the design may be changed in consideration of the size of the operation handle 1 such as 20 cm, 25 cm, or 35 cm.

[Second Embodiment]
Next, a second embodiment of the present invention will be described with reference to FIG. In the second embodiment, unlike the first embodiment in which one display unit support arm is provided in the remote control device, an example of a configuration in which a plurality of display unit support arms are attached to the remote control device will be described. To do.

  As shown in FIG. 12, a plurality of display unit support arms 4 are attached to the remote control device 400 of the second embodiment. In the remote operation device 400, the display unit support arm 4 includes display unit support arms 4a and 4b. In the example shown in FIG. 12, the display unit support arms 4a and 4b of the remote control device 400 are attached with a scope type display unit 3a and a non-scope type display unit 3b as the display unit 3, respectively. The two display units 3 are arranged side by side in the left-right direction (X direction). The display unit support arms 4a and 4b are examples of the “first display unit support arm” and the “second display unit support arm” in the claims, respectively.

  In other words, the remote operation device 400 is provided with a plurality (two) of mounted parts 41. Specifically, the remote control device 400 is provided with a plurality (two) of display unit support arms 4 (4a, 4b). And the to-be-attached part 41 is provided in the front-end | tip of each display part support arm 4a and 4b. Thereby, since both the scope type display part 3a and the non-scope type display part 3b can be attached to the remote control device 400, the versatility of the display part 3 can be effectively enhanced.

  In the second embodiment, the non-scope type display unit 3b used on one side displays at least one of an image of a surgical part acquired in advance, information indicating a surgical state, and operation information. For example, an X-ray captured image or a magnetic resonance image captured in advance is displayed on the one non-scope type display unit 3b. The other (other) scope-type or non-scope-type display unit displays a 3D image or 2D image acquired from the endoscope 201b. Accordingly, the operator O mainly obtains at least one auxiliary information among the surgical part image, the information indicating the surgical state, and the operation information acquired in advance while viewing the endoscopic image of the other display unit. While referring to it, it is possible to expand versatility and expandability such as performing an operation.

  As a result, the remote control device 400 according to the second embodiment is configured such that the scope-type display unit 3a or the non-scope-type display unit 3b is selectively detachably attached as the main display unit 3, and further auxiliary A non-scope type display unit 3b is attached as a display unit. Thus, auxiliary information can be referred to while either an immersive remote control device or an open remote control device can be selected. In addition, since a plurality of mounted parts are provided, it is possible to freely select whether the main display part is installed on the left or right side.

  The display unit support arm 4a includes a joint 43a, a joint 43b, and a joint 43c as the joint 43. In addition, the display unit support arm 4 a includes a parallel link mechanism 44 a as the parallel link mechanism 44. The joints 43a, 43b and 43c are provided with electromagnetic brakes 431a, 431b and 431c, respectively, as the electromagnetic brake 431. The parallel link mechanism 44 a is provided with an electromagnetic brake 441 a as the electromagnetic brake 441. The joints 43a, 43b, 43c and the parallel link mechanism 44a are examples of “joint” and “first joint” in the claims, and the electromagnetic brakes 431a, 431b, 431c, and 441a are in the claims. It is an example of a “lock mechanism” and a “first lock mechanism”.

  The display unit support arm 4b includes a joint 43d, a joint 43e, and a joint 43f as the joint 43. In addition, the display unit support arm 4 b includes a parallel link mechanism 44 b as the parallel link mechanism 44. As shown in FIG. 3, electromagnetic brakes 431d, 431e, and 431f are provided as joints 43d, 43e, and 43f, respectively, as electromagnetic brakes 431. The parallel link mechanism 44b is provided with an electromagnetic brake 441b as the electromagnetic brake 441. The joints 43d, 43e, 43f, and the parallel link mechanism 44b are examples of “joint” and “second joint” in the claims, and the electromagnetic brakes 431d, 431e, 431f, and 441b are in the claims. It is an example of a “lock mechanism” and a “second lock mechanism”.

  One trigger lever 321a is provided on each of the left and right sides of the scope type display unit 3a. One trigger lever 321b is provided on each of the left and right sides of the non-scope type display unit 3b. When the trigger lever 321 is grasped together with the grip portion 32, the release operation is performed. Specifically, the trigger lever 321a is configured to release the locked state of the electromagnetic brakes 431a to 431c and 441a of the display unit support arm 4a. The trigger lever 321b is configured to release the locked state of the electromagnetic brakes 431d to 431f and 441b of the display unit support arm 4b. That is, the joints 43a to 43c and the parallel link mechanism 44a of the display unit support arm 4a are unlocked independently from the locked state of the joints 43d to 43f and the parallel link mechanism 44b of the display unit support arm 4b. Is possible. The trigger levers 321a and 321b are examples of the “first release mechanism” and the “second release mechanism” in the claims, respectively.

  In the example of FIG. 12, the scope-type display unit 3a and the non-scope-type display unit 3b are attached to the two attached parts 41, but the scope-type display part 3a is attached to both of the two attached parts 41. Alternatively, the non-scope type display unit 3b may be attached to both of the two mounted parts 41.

  In addition, the other structure of 2nd Embodiment is the same as that of the said 1st Embodiment.

(Modification of release mechanism)
In the above-described embodiment, an example in which all the joints (joints 43a to 43c and the parallel link mechanism 44) are released only after pressing both the left and right trigger levers 321 of the display unit 3 is shown. The mode of releasing the mechanism is not limited to this.

  For example, only one trigger lever 321 of the two left and right trigger levers 321 of the display unit 3 may be configured to release all joints. In this case, since the operator O can move the position of the display unit 3 with one hand, the position of the display unit 3 can be changed more easily. Moreover, even if the operator O is left-handed or right-handed, the position of the display unit 3 can be changed with one hand.

  Further, only one trigger lever 321 may be provided on the display unit 3. With such a configuration, since the physical mechanism around the display unit 3 is reduced, contact with other parts can be reduced. The display unit 3 to be used may be appropriately installed for a left-handed operator or a right-handed operator. When the remote operation device 100 has a mounted portion to which the display unit 3 can be attached and detached, a left-handed operator display unit and a right-handed operator display unit can be appropriately selected and used.

  Further, three or more trigger levers 321 may be provided. For example, when two trigger levers 321 are provided on the left and right sides of the display unit 3 and one of the foot pedals is a trigger lever 321, the display unit 3 is moved only when the three trigger levers 321 are pressed. . In this case, the position of the display unit 3 can be changed only when the operator O has a more reliable intention to move the position of the display unit 3.

  In the case where a plurality of trigger levers 321 are provided, joints that are released by the respective trigger levers 321 may be separated. For example, when two trigger levers 321 are provided on the left and right sides of the display unit 3, one of the left and right trigger levers is at least one of the joints that contribute to the horizontal movement of the display unit 3 (for example, only the joint 43a). The lock state is released, and the other of the left and right trigger levers releases the lock state of at least one of the joints (parallel link mechanism 44 in the example of FIG. 3) that contributes to the movement of the display unit 3 in the vertical direction. You may do it. With such a configuration, in addition to the advantages of providing the plurality of trigger levers described so far, it is also possible to provide a restriction that the display unit 3 is moved only in the direction in which it is desired to move. In addition, with such a configuration, only the necessary joints are in an operating state, so that the burden on the display unit support arm 4 when the display unit 3 moves is reduced.

  Further, when each joint of the display unit support arm 4 includes a motor and a position detector (for example, an encoder), the movement range of the display unit 3 can be limited in a controllable manner. For example, it can restrict | limit so that the display part 3 may be translated along a certain plane. For example, as shown in FIG. 11, the display surface of the display unit 3 is supported by the display unit support arm 4 in a state parallel to a plane PL inclined at 10 degrees from the XZ plane about the X axis in the XYZ coordinates. Then, the control unit 61 can perform control so that the display unit 3 can be translated only along the plane PL. For example, the plane PL may be determined according to the state of the angle adjustment joint 35. Further, the plane PL may be settable by the operation unit 8b. That is, you may enable it to input the angle of the plane PL to translate from the operation part 8b.

  In addition, in order to change the position and orientation of the display unit 3 more safely, the control unit 61 locks each joint even if it detects the pressing operation of the trigger lever 321 when the operation handle 1 is operated. You may make it control so that a state may not be cancelled | released. Whether or not the operation handle 1 is operated can be detected by, for example, a motion sensor. Accordingly, it is prohibited to operate the trigger lever 321 with the other hand while operating the operation handle 1 with one hand, and the safety as a medical device can be improved.

  Then, which of the variations of the release mechanism as described above, that is, the condition for operating the joint lock mechanism by the trigger lever 321 as the release mechanism can be set by the operation unit 8b (see FIG. 4). It is preferable to keep it. For example, the following setting may be considered.

(1) When all of the plurality of trigger levers 321 are released, all joints (joint 43 and parallel link mechanism 44) are unlocked, or at least one of the plurality of trigger levers 321 (2) When the trigger levers 321 are provided at the left and right separated positions of the display unit 3, all the joints are operated by any of the trigger levers. Whether to unlock (for example, for left-handed or right-handed operators)
(3) When a plurality of trigger levers 321 are provided, which joint is unlocked by each trigger lever (4) The range in which the display unit 3 can move (for example, parallel to the tilt of the display unit 3) Can only move along a flat surface)
(5) Selection of display unit 3 that can be moved when a plurality of display unit support arms 4 are provided (another modification)
The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is shown not by the above description of the embodiment but by the scope of claims for patent, and further includes all modifications (modifications) within the meaning and scope equivalent to the scope of claims for patent.

  For example, in the said 1st Embodiment, the example of the structure by which the one display part support arm which supports a display part is provided is shown, and in the said 2nd Embodiment, the two display part support arms which support a display part are shown. Although the example of the structure provided was shown, this invention is not limited to this. In the present invention, three or more display unit support arms for supporting the display unit may be provided. That is, three or more display units may be provided in the remote control device.

  Moreover, in the said 1st and 2nd embodiment, although the example of the structure by which the display part support arm was provided with the several joint was shown, this invention is not limited to this. In the present invention, one joint may be provided on the display unit support arm.

  Moreover, in the said 1st and 2nd embodiment, although the example of the structure which can attach or detach a display part with respect to a display part support arm was shown, this invention is not limited to this. In the present invention, the display unit may be fixedly provided with respect to the display unit support arm.

  Moreover, in the said 2nd Embodiment, although the example of the structure by which the remote control apparatus was provided with the scope type display part and the non-scope type display part was shown, this invention is not limited to this. In the present invention, the remote control device may be provided with only a scope-type display unit or may be provided with only a non-scope-type display unit.

  In the first and second embodiments, the example in which the attached display unit is connected to the remote control device via a wired cable so that information communication is possible has been described. However, the present invention is not limited to this. Absent. In the present invention, the attached display unit may be connected to the remote control device so that information communication is possible by wireless communication.

  In the first and second embodiments, the example in which the support mechanism moves the operation handle and the armrest in the vertical direction has been described. However, the present invention is not limited to this. In the present invention, the support mechanism may move the operation handle and the armrest in the horizontal direction in addition to the vertical direction.

  1: Operation handle, 3: Display unit, 3a: Scope type display unit, 3b: Non-scope type display unit, 4: Display unit support arm, 4a: Display unit support arm (first display unit support arm), 4b: Display Part support arm (second display part support arm), 8b: operation part, 9: support mechanism, 32: gripping part, 35: angle adjusting joint, 41: mounted part, 43: joint, 43a, 43b, 43c: joint (First joint), 43d, 43e, 43f: joint (second joint), 44: parallel link mechanism (joint), 44a: parallel link mechanism (first joint), 44b: parallel link mechanism (second joint), 100, 400: remote control device, 201b: endoscope (imaging unit), 321: trigger lever (release mechanism), 321a: trigger lever (first release mechanism), 321b: trigger lever (second release mechanism), 431 : Electromagnetic Key (lock mechanism), 431a, 431b, 431c: Electromagnetic brake (first lock mechanism), 431d, 431e, 431f: Electromagnetic brake (second lock mechanism), 441: Electromagnetic brake (lock mechanism), 441a: Electromagnetic brake (First lock mechanism), 441b: electromagnetic brake (second lock mechanism)

A remote control device for a medical instrument according to a first aspect of the present invention displays an image captured by an imaging unit, and includes a scope-type display unit for an operator to look into the displayed image , a joint, and a joint. includes an electromagnetic brake as a locking mechanism to the locked state, a scope display portion support arm for supporting the scope display section, and the operating handle for the operator to operate the medical device remotely, the operator operates Accordingly, obtain Preparations and releasing mechanism for releasing the locked state of the scope display section of the support arm joints, and.

A remote control device for a medical instrument according to a second aspect of the present invention includes an electromagnetic brake as a first lock mechanism that locks the first joint and the first joint, and displays an image that the operator looks into and displays. a scope display portion support arm for supporting the scope display unit for viewing includes an electromagnetic brake of the second joint and the second joint as a second locking mechanism to the locked state, the non-supporting non-scope display section A scope-type display unit support arm , an operation handle for the operator to remotely operate the medical instrument, and a first operation for releasing the first joint lock state of the scope-type display unit support arm by the operator 's operation. obtain Bei and release mechanism, by which the operator operates, and a second release mechanism for releasing the locked state of the second joint of the non-scope display portion support arm, the.

Claims (20)

A display unit for displaying an image captured by the imaging unit;
A display unit support arm including a joint and supporting the display unit;
A gripping part provided in the display part;
An operation handle for remotely operating a medical instrument;
A locking mechanism that locks the joint;
A release mechanism for releasing the lock state of the joint,
The release mechanism is a remote control device for a medical instrument provided in the grip portion.   The medical device remote control device according to claim 1, wherein the lock mechanism includes an electromagnetic brake.   The remote operation device for a medical instrument according to claim 1, further comprising an operation unit that sets a condition for operating the lock mechanism by the release mechanism.   The remote operation device for a medical instrument according to any one of claims 1 to 3, wherein a plurality of the grip portion and the release mechanism are provided.   The remote control device for a medical instrument according to claim 4, wherein when all of the plurality of release mechanisms are released, the lock state of the joint is released.   The condition is that the joint is unlocked when all of the plurality of release mechanisms are released, or when at least one of the plurality of release mechanisms is released. The remote control device for a medical instrument according to claim 4 or 5 dependent on claim 3, wherein the locked state is released.   The remote operation device for a medical instrument according to claim 1, wherein the display unit support arm includes a plurality of the joints.   Of the plurality of release mechanisms, one of the plurality of release mechanisms releases the locked state of one of the plurality of joints, and among the plurality of release mechanisms, the other release mechanism releases the other of the plurality of joints. The remote control device for a medical instrument according to claim 7, which is dependent on any one of claims 4 to 6, wherein the joint is unlocked.   The condition according to claim 7 or 8 depending on claim 3 or 4, wherein the condition is which release mechanism of the plurality of release mechanisms releases the locked state of which joint among the plurality of joints. Remote control device.   The remote operation device for a medical instrument according to any one of claims 1 to 9, wherein the display unit support arm is disposed on a side opposite to the operator with respect to the display unit.   The remote operation device for a medical instrument according to claim 1, wherein the display unit support arm includes a parallel link mechanism.   The medical instrument remote control device according to claim 11, wherein the parallel link mechanism is configured to move the display unit in a vertical direction.   The remote operation device for a medical instrument according to any one of claims 1 to 12, wherein the display unit includes a scope type display unit.   The angle adjustment joint provided between the said display part support arm and the said display part separately from the said joint of the said display part support arm, and adjusting the angle of the display surface of the said display part is provided. The remote control device for a medical instrument according to any one of 13.   The remote operation device for a medical instrument according to any one of claims 1 to 14, wherein the operation of the display unit is limited so as to translate along a certain plane.   16. The remote control device for a medical instrument according to claim 15, which is dependent on claim 14, wherein the plane is determined according to a state of the angle adjustment joint.   16. The remote operation device for a medical instrument according to claim 15, which is dependent on claim 3, wherein the plane can be set by the operation unit.   The remote control device for a medical instrument according to any one of claims 1 to 17, further comprising a mounted portion to which the scope-type display unit and the non-scope-type display unit are selectively detachably attached. A support mechanism for supporting the operation handle;
The support mechanism includes a first mode for holding the operation handle at a position adapted for the operator to operate the operation handle in a standing position, and a position adapted for the operator to operate the operation handle in a sitting position. The remote control device for a medical instrument according to any one of claims 1 to 18, wherein the remote control device is configured to be capable of transitioning between a second form holding the operation handle. A first display unit support arm including a first joint and supporting a scope type display unit;
A second display unit support arm including a second joint and supporting the non-scope type display unit;
A first gripping part provided in the scope type display part;
A second gripping part provided in the non-scope type display part;
An operation handle for remotely operating a medical instrument;
A first locking mechanism that locks the first joint;
A second locking mechanism that locks the second joint;
A first release mechanism for releasing the locked state of the first joint;
A second release mechanism for releasing the locked state of the second joint,
The remote operation device for a medical instrument, wherein the first release mechanism is provided in the first grip portion, and the second release mechanism is provided in the second grip portion.

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