JP2020073022A - Remote operation device, surgery system, and specification method of operation target pedal - Google Patents

Abstract

To provide a remote operation device capable of preventing reduction of precision of detecting presence of a foot operating a pedal to be operated among a plurality of pedals.SOLUTION: A remote operation device 100 includes: an operation handle 1 for remotely operating a medical device; an operation pedal part 2 including a plurality of pedals 20 operated by being pushed downward by a foot for performing a function related to the medical device, and a sensor 26 for detecting presence of the foot operating the pedal 20; and a control part 61 that receives detection information from the sensor 26. When the control part 61 receives the detection information from the plurality of sensors 26 arranged in the vicinity of a solidification pedal 21 and a cutting pedal 22, the control part determines that there is a foot operating the solidification pedal 21 and the cutting pedal 22.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a remote control device, a surgery system, and a method of identifying a pedal to be operated.

  Conventionally, a remote control device for operating a medical instrument is known (for example, refer to Patent Document 1).

  Patent Document 1 discloses a remote control device provided with a foot unit including a plurality of foot pedals and a presence sensor that detects the presence of the operator's foot. Further, the remote operation device of Patent Document 1 detects the presence of an operator's foot, and thereby, on the display device of the remote operation device, highlights the icon of the surgical instrument connected to the corresponding foot pedal to operate the operation device. It is configured to convey the target foot pedal to the operator. Further, in the remote control device of Patent Document 1, the presence sensor is configured to detect the presence of the operator's foot near one or more foot pedals.

Japanese Patent Publication No. 2015-534476

  However, in the remote operation device of Patent Document 1, since the presence sensor detects the presence of the foot of the operator near one or more foot pedals, the presence sensor detects the feet near the plurality of foot pedals. In such a case, there is a disadvantage that it is difficult to specify one foot pedal to be operated. Therefore, there is a problem in that the accuracy of detecting the presence of the foot operating the pedal to be operated among the plurality of pedals decreases.

  The present invention provides a remote control device and a surgery system capable of suppressing a decrease in accuracy of detecting the presence of a foot operating a pedal to be operated among a plurality of pedals.

  A remote control device according to a first aspect of the present invention includes an operation handle for remotely operating a medical instrument, and a plurality of pedals for operating a medical instrument by pushing the foot downwards. And an operation pedal unit including a sensor for detecting the presence of a foot operating the pedal, and a control unit receiving detection information from the sensor, the sensor being one of a plurality of pedals. If a plurality of sensors are provided in the vicinity of one pedal and the detection information is received from a plurality of sensors arranged in the vicinity of one first pedal, it is determined that there is a foot operating the first pedal. judge. Note that the detected "foot" does not have to be the bare foot of the operator, and shoes or socks such as shoes or socks that are attached to (weared on) the operator's foot are also included in the "foot".

  The surgical system according to the second aspect of the present invention includes an operation handle for remotely operating a medical instrument, and a plurality of pedals for performing functions related to the medical instrument, which are operated by pushing downward with respective feet. A remote control device having an operation pedal part including a sensor for detecting the presence of a foot operating a pedal, and a patient-side device having a medical device operated by the remote control device, and a control part, A plurality of sensors are provided in the vicinity of one first pedal of the plurality of pedals, and the control unit provides the detection information from the plurality of sensors arranged in the vicinity of the one first pedal. If received, it is determined that there is a foot operating the first pedal.

  A method of identifying a pedal to be operated according to a third aspect of the present invention identifies a pedal to be operated from among a plurality of pedals for performing a function related to a medical device, which is operated by pushing each foot downward. And determining whether or not a plurality of sensors arranged in the vicinity of one pedal detect the presence of a foot operating the pedal, and a plurality of sensors detecting the presence of the foot operating the pedal. Specifying that the pedal arranged in the vicinity of the plurality of sensors is the pedal to be operated when the presence is detected.

  ADVANTAGE OF THE INVENTION According to this invention, it can suppress that the precision which detects the presence of the foot which operates the pedal of operation object among several pedals falls.

It is the figure which showed the outline of the remote control device by 1st Embodiment. FIG. 3 is a diagram showing a state in which a scope type display unit is attached to the remote control device according to the first embodiment. FIG. 3 is a block diagram showing a control configuration of the remote control device according to the first embodiment. FIG. 3 is a perspective view showing an operation pedal portion of the remote operation device according to the first embodiment. FIG. 3 is a plan view showing an operation pedal portion of the remote operation device according to the first embodiment. FIG. 3 is a front view showing an operation pedal portion of the remote operation device according to the first embodiment. It is a figure for explaining an example of allocation of an operation pedal part of a remote control by a 1st embodiment. It is a side view showing a state of the first form of the remote control device according to the first embodiment. It is a side view showing the state of the 2nd form of the remote control by a 1st embodiment. FIG. 3 is a diagram showing a model of an operator of the remote control device according to the first embodiment. FIG. 3 is a diagram showing a state where a non-scope type display unit is attached to the remote control device according to the first embodiment. It is a schematic diagram for explaining the 1st example of the lock mechanism and lock release mechanism of the remote control by a 1st embodiment. FIG. 9 is a schematic diagram for explaining a second example of the lock mechanism and the lock release mechanism of the remote control device according to the first embodiment. It is a schematic diagram for explaining the 3rd example of the lock mechanism and lock release mechanism of the remote control by a 1st embodiment. 6 is a flowchart for explaining an operation target pedal identification process by a control unit of the remote operation device according to the first embodiment. It is the figure which showed the remote control by 2nd Embodiment. It is the figure which showed the remote control by 3rd Embodiment. It is a figure showing the remote control by a 4th embodiment. It is the figure which showed the remote control by the modification of 1st-4th embodiment.

  Embodiments will be described below with reference to the drawings.

[First Embodiment]
(Configuration of remote control device)
The configuration of the remote operation device 100 according to the first embodiment will be described with reference to FIGS. 1 to 14.

  As shown in FIG. 1, the remote control device 100 is provided to remotely control a medical instrument provided in the patient-side system 200. When the operation mode command to be executed by the patient-side system 200 is input to the remote operation device 100 by the operator O who is a surgeon, the remote operation device 100 transmits the operation mode command to the patient via the controller 206. It is transmitted to the side system 200. Then, in response to the operation mode command transmitted from the remote control device 100, the patient side system 200 operates a surgical instrument (surgical instrument) held by the surgical manipulator 201, a medical instrument such as an endoscope. Thereby, minimally invasive surgery is performed. The surgical system includes a remote control device 100 and a patient-side system 200 having a surgical manipulator 201. The patient-side system 200 is an example of the “patient-side device” in the claims. The endoscope 201b is an example of the "imaging unit" 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 has a plurality of surgical manipulators 201, one of which holds an endoscope 201b, and the other surgical manipulator 201 holds 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 commonly supported 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 provided via the controller 206.

  The platform 203 is supported by a positioner 202 mounted on the floor of the operating room. In the positioner 202, a column portion 204 having a vertically movable lifting shaft 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 its tip. The instrument 201a includes a housing attached to the instrument arm 201A and an end effector provided at the tip of an elongated shaft. Examples of the end effector include, but are not limited to, grasping forceps, scissors, hooks, high-frequency knives, snare wires, clamps, and staplers, and various treatment tools can be applied. In the operation 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 as a surgical site. Is located near the.

  An endoscope 201b (see FIG. 3) as a medical instrument is detachably attached to the tip of the camera arm 201B. The endoscope 201b is for photographing the inside of the body cavity of the patient P, and the photographed image is output to the remote control device 100. A 3D endoscope or a 2D endoscope capable of capturing a three-dimensional image is used as the endoscope 201b. In the surgery using the patient-side system 200, the camera arm 201B is introduced into the body of the patient P via the trocar indwelling on the body surface of the patient P, and the endoscope 201b is arranged near the surgical site.

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

  The operation mode to be executed by the instrument 201a is an operation mode (a series of positions and postures) of the instrument 201a and an operation mode realized by the individual function 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. Further, 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, supply of current to the high-frequency knife. Further, 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 binding state releasing operation. Further, it may be an operation of burning off the surgical target site by supplying an electric current to the bipolar or monopolar.

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

  As shown in FIG. 1, the remote control device 100 is provided with a cover 101. 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) side, and the upper 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 3, the remote control 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. The remote control device 100 also includes a posture operation unit 8 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 an operator O for operating a medical instrument (the instrument 201a, the endoscope 201b). A pair of operation handles 1 is provided along the X direction. That is, the operation handle 1 on the X2 direction side (right side) of the pair of operation handles 1 is operated by the right hand of the operator O, and the operation handle 1 on the X1 direction side (left side) of the pair of operation handles 1 is operated. It is operated by the left hand of the person O.

  Further, the operation handle 1 is attached to the support portion 91 of the support mechanism 9. The operation handle 1 is arranged so as to extend from the rear side (Y2 direction) side of the remote operation device 100 toward the front side (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. 8 and 9). It is configured to be able to. That is, the operation handle 1 is configured to be movable with respect to the support portion 91 in the up-down direction (Z direction), the left-right direction (X direction), and the front-rear direction (Y direction). Each joint between the support portion 91 and the operation handle 1 is provided with a position detection portion (not shown) that detects the positional relationship between the joints. 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 control 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 an operation unit on the master side in the master-slave type system, and the instrument arm 201A and the camera arm 201B which hold the medical instrument constitute an operation unit on the slave side. When the operator O operates the operation handle 1, the movement of the operation handle 1 is caused by movement of the distal end portion of the instrument arm 201A (end effector of the instrument 201a) or the distal end portion 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.

  Further, 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 1/2, the end effector of the instrument 201a is controlled to move a moving distance of 1/2 of the moving distance of the operation handle 1. This allows precise surgery to be performed accurately. The operation handle 1 is attached to the base 7 and is formed so as to extend in the Y direction toward the operator O.

  As shown in FIGS. 4 to 6, the operation pedal unit 2 includes a plurality of pedals 20 for executing functions related to medical instruments. The operation pedal portion 2 includes a base portion 2a on which a plurality of pedals 20 are arranged, and a wall portion 2b provided so as to stand upright from the base portion 2a. The pedal 20 includes a coagulation pedal 21, a disconnection pedal 22, a camera pedal 23, and a clutch pedal 24. Further, the operation pedal portion 2 is provided with a side pedal 25. The coagulation pedal 21, the disconnection pedal 22, the camera pedal 23, and the clutch pedal 24 are operated by pressing them downward with their feet. The side pedal 25 is operated by pushing it in the horizontal direction. The pedal 20 receives an operation, for example, when it is pressed by about 10 mm. Further, the pushing force of the pedal 20 is set according to the standard so that the pedal 20 can be operated with the lightest force possible. The pedal 20 is operated by the foot of the operator O. The coagulation pedal 21 and the cutting pedal 22 are examples of the "first pedal" in the claims. The camera pedal 23 and the clutch pedal 24 are examples of the "second pedal" in the claims.

  In addition, the operation pedal unit 2 includes a plurality of sensors 26 for detecting the presence of a foot operating the pedal 20. The sensor 26 includes sensors 26a, 26b, 26c, 26d, 26e, 26f, 26g. Further, each of the plurality of sensors 26 includes a light emitting unit 261 and a light receiving unit 262. The sensor 26 detects the presence of the foot when the light from the light emitting unit 261 is blocked by the foot and the light reception by the light receiving unit 262 is interrupted. That is, the sensor 26 is a cutoff type sensor. One of the light emitting unit 261 and the light receiving unit 262 is provided on the base 2a. The other of the light emitting portion 261 and the light receiving portion 262 is provided on the wall portion 2b.

  The detection information detected by the sensor 26 is transmitted to the control unit 61, and the control unit 61 that has received the detection information determines whether or not there is a foot operating the corresponding pedal 20.

  The coagulation pedal 21 can perform an operation of coagulating a surgical site using a surgical instrument. Specifically, when the coagulation pedal 21 is operated, a voltage for coagulation is applied to the instrument 201a to coagulate the surgical site. The coagulation pedal 21 includes a coagulation pedal 21a and a coagulation pedal 21b. That is, a plurality (two) of coagulation pedals 21 are provided. The coagulation pedal 21a is arranged on the left side (X1 direction side) of the coagulation pedal 21b. The coagulation pedal 21a is used, for example, in association with the instrument 201a of the instrument arm 201A operated by the left operation handle 1. The coagulation pedal 21b is used, for example, in association with the instrument 201a of the instrument arm 201A operated by the right operation handle 1.

  The cutting pedal 22 can perform an operation of cutting a surgical site using a surgical instrument. Specifically, the cutting pedal 22 is operated to apply a cutting voltage to the instrument 201a, thereby cutting the surgical site. The cutting pedal 22 includes a cutting pedal 22a and a cutting pedal 22b. That is, a plurality (two) of cutting pedals 22 are provided. The cutting pedal 22a is arranged on the left side (X1 direction side) of the cutting pedal 22b. The cutting pedal 22a is used, for example, in association with the instrument 201a of the instrument arm 201A operated by the left operation handle 1. The disconnection pedal 22b is used, for example, in association with the instrument 201a of the instrument arm 201A operated by the right operation handle 1.

  The camera pedal 23 is used to operate the position and posture of the endoscope 201b that images the inside of the body cavity. Specifically, the camera pedal 23 enables the operation by the operation handle 1 of the endoscope 201b. That is, while the camera pedal 23 is being pressed, the position and orientation of the endoscope 201b can be operated by the operation handle 1. For example, the endoscope 201b is operated by using both the left and right operation handles 1. Specifically, the endoscope 201b is rotated by rotating the left and right operation handles 1 around the midpoint of the left and right operation handles 1. Further, by pushing in the left and right operation handles 1 together, the endoscope 201b advances to the back. Further, the endoscope 201b is returned to the front by pulling the left and right operation handles 1 together. Further, by moving both the left and right operation handles 1 vertically and horizontally, the endoscope 201b moves vertically and horizontally.

  The clutch pedal 24 is used when the operation connection between the surgical manipulator 201 and the operation handle 1 is temporarily disconnected to stop the operation of the surgical instrument. Specifically, while the clutch pedal 24 is being operated, even if the operation handle 1 is operated, the surgical manipulator 201 of the patient-side system 200 does not operate. For example, when the operation handle 1 comes near the end of the movable range by the operation, the clutch pedal 24 is operated to temporarily disconnect the operation connection and return the operation handle 1 to the vicinity of the central position. You can Then, when the operation of the clutch pedal 24 is stopped, the surgical manipulator 201 and the operation handle 1 are reconnected, and the operation of the operation handle 1 can be restarted near the center.

  The side pedals 25 are used to switch the instrument arm 201A operated by the operation handle 1. For example, four surgical manipulators 201 are provided, and three instrument arms 201A other than the camera arm 201B are operated by the left and right operation handles 1 by operating the side pedals 25. 201A is switched. The side pedal 25 is operated by being pushed leftward (X1 direction). For example, by operating the side pedal 25, the instrument arm 201A operated by the right operation handle 1 is switched. That is, the instrument arm 201A operated by the left operation handle 1 is not changed, and the instrument arm 201A operated by the right operation handle 1 is switched.

  As shown in FIGS. 4 to 6, the pedal 20 is a side pedal 25, a camera pedal 23, a clutch pedal 24, a disconnection pedal 22a, a coagulation pedal 21a, and a coagulation pedal 21a, from the left side (X1 side) to the right side (X2 side). The cutting pedal 22b and the coagulation pedal 21a are arranged in this order. The plurality of pedals 20 (camera pedal 23, clutch pedal 24, disconnection pedal 22a, coagulation pedal 21a, disconnection pedal 22b, coagulation pedal 21a) are arranged side by side in the width direction (X direction) of the operation pedal portion 2. There is.

  That is, the coagulation pedal 21 and the cutting pedal 22 are alternately arranged in the horizontal direction (the width direction (X direction) of the operation pedal portion 2). Thereby, each of the plurality of coagulation pedals 21 and each of the plurality of cutting pedals 22 can be operated in association with each of the instruments 201a operated by the left and right operation handles 1. Further, the plurality of coagulation pedals 21 and the plurality of cutting pedals 22 are alternately arranged continuously on one side (right side) with respect to the center of the operation pedal portion 2 in the width direction (X direction).

  The arrangement of the pedals shown in FIGS. 4 to 6 is suitable for operating the set of the coagulation pedal 21 and the cutting pedal 22 assigned to each of the left and right operation handles 1 with only the right foot. The pair of pedals 22a is arranged on the left side (X1 side) of the camera pedal 23 and the clutch pedal 24, and the camera pedal 23 and the clutch pedal 24 are arranged at the center (the pair of the coagulation pedal 21a and the cutting pedal 22a and the coagulation pedal 21b and the cutting pedal 22b). The coagulation pedal 21a assigned to the left operation handle 1 and the cutting pedal 22a are operated by the left foot, and the coagulation pedal 21b assigned to the right operation handle 1 is disconnected. The pedal 22b has an arrangement suitable for being operated by the right foot.

  The operation pedal portion 2 is arranged such that a plurality of pedals 20 that are operated by being pushed downward are arranged at positions where they do not overlap each other in a planar position and at positions where they overlap each other at a height position. That is, the plurality of pedals 20 are arranged so that the positions in the width direction (X direction) are different, and at least a part of each pedal 20 is at the same height position. With this, unlike the case where the height positions of the plurality of pedals 20 are configured in upper and lower two stages, it is not necessary to greatly raise and lower the foot for the operation. That is, the plurality of pedals 20 including the coagulation pedal 21 and the cutting pedal 22 can be operated with the toes while the heel is attached. As a result, the operability of the pedal 20 can be improved while ensuring the number of types of operations to be input.

  Specifically, the coagulation pedal 21, the disconnection pedal 22, the camera pedal 23, and the clutch pedal 24 are arranged at positions where they do not overlap each other in the plane position, and at positions that overlap each other at the height position. There is.

  The side pedals 25 are also preferably arranged so that they can be operated with the heel attached, and are arranged in a position where they do not overlap each other in the plane position with a plurality of pedals that are operated downward, and also overlap each other in the height position. It is preferably arranged in a position. The side pedal 25 may also be changed to a pedal operated by pushing it downward.

  Further, the plurality of pedals 20 that are operated downwardly have different height positions of the upper ends of the adjacent pedals 20. With this, the type of the pedal 20 can be determined without visually checking the pedal 20, so that the pedal 20 can be operated while looking at the display unit 3. As shown in FIG. 6, for example, the cutting pedal 22 and the camera pedal 23 are arranged such that the height positions of the upper ends thereof are apart from the floor surface by a distance ha. Further, the coagulation pedal 21 and the clutch pedal 24 are arranged such that the height position of the upper end is a distance hb away from the floor surface.

  That is, the height position of the upper end of the cutting pedal 22 is the first height position, and the height position of the upper end of the coagulation pedal 21 is the second height position different from the first height position. This can prevent the cutting pedal 22 and the coagulation pedal 21 from being operated by mistake. The height position of the upper end of the cutting pedal 22 may be the second height position, and the height position of the upper end of the coagulation pedal 21 may be the first height position.

  Here, the distance ha from the floor surface at the first height position is preferably 1.5 times or more the distance hb from the floor surface at the second height position. Accordingly, the cutting pedal 22 and the coagulation pedal 21 can be easily distinguished and operated without visually recognizing them. Further, it is more preferable that the distance ha from the floor surface at the first height position is approximately twice the distance hb from the floor surface at the second height position. As a result, the cutting pedal 22 and the coagulation pedal 21 can be more easily distinguished from each other, and the first height position can be prevented from becoming too high.

  The distance ha from the floor surface at the first height position is, for example, about 50 mm. The distance hb from the floor surface at the second height position is, for example, about 25 mm. As a result, the operator O can operate each of the cutting pedal 22 and the coagulation pedal 21 with the heel attached, so that the operator O does not need to lift the foot greatly. The distance ha from the floor surface at the first height position may be in the range of about 10 mm or more and about 200 mm or less. Further, the distance hb from the floor surface at the second height position may be in the range of about 5 mm or more and about 100 mm or less.

  Further, as shown in FIG. 6, in the operation pedal portion 2, the lower ends of the plurality of pedals 20 are arranged at substantially the same height.

  Regarding the side pedals 25, the upper end position and the lower end position may be arbitrary, but since it is preferable that the pedal contact area is large, the upper end is preferably in a high position and the lower end is in a low position. In the example shown in FIG. 6, the upper end position and the lower end position of the side pedal 25 are the same as those of the camera pedal 23.

  Further, as shown in FIG. 5, for example, the cutting pedal 22 and the camera pedal 23 project by a distance d1 in a plan view (as viewed in the Z direction). Further, the coagulation pedal 21 and the clutch pedal 24 are projected by a distance d2 in a plan view. For example, the distance d2 is larger than the distance d1. This allows the pedal 20 to be easily distinguished and operated. The protrusion distances of the pedals 20 in plan view may be different from each other or may be substantially the same. In this case, each of the pedals 20 may protrude in the fan shape by the same distance.

  The coagulation pedal 21 and the clutch pedal 24 have different shapes in plan view. Also by this, the type of the pedal 20 can be easily distinguished and operated. That is, the pedals 20 having different shapes are alternately arranged in the horizontal direction.

  As shown in FIG. 5, in the operation pedal portion 2, a plurality of pedals 20 are arranged in a fan shape in a plan view (as viewed in the Z direction). Specifically, in the operation pedal portion 2, the plurality of pedals 20 are arranged in a fan shape on one side with respect to the center and the plurality of pedals 20 are fan shaped on the other side with respect to the center in a plan view. It is located in. Thus, by arranging the plurality of pedals 20 in a fan shape with the operator O as the center, the operator O can operate the plurality of pedals 20 by rotating the toes with the heel attached. .. As a result, the operability of the pedal 20 can be improved while ensuring the number of types of operations to be input.

  For example, as shown in FIGS. 4 and 5, the camera pedal 23 and the clutch pedal 24 are provided on the left side (X1 direction side) with respect to the center. The camera pedal 23 is arranged so as to extend toward the front side (Y1 direction side) while being inclined to the right side (X2 direction side). The clutch pedal 24 is arranged so as to extend substantially in the front-rear direction (Y direction). Accordingly, the operator O can easily operate the camera pedal 23 and the clutch pedal 24 with the left foot.

  The coagulation pedal 21 (21a and 21b) and the cutting pedal 22 (22a and 22b) are provided on the right side (X2 direction side) with respect to the center. Further, the cutting pedal 22a is arranged so as to extend toward the front side (Y1 direction side) while being inclined to the right side (X2 direction side). The coagulation pedal 21a is arranged so as to extend substantially in the front-rear direction (Y direction). The cutting pedal 22b is arranged so as to extend toward the front side (Y1 direction side) while being inclined to the left side (X1 direction side). The coagulation pedal 21b is arranged so as to extend further toward the left side (X1 direction side) toward the front side (Y1 direction side). This allows the operator O to easily operate the coagulation pedal 21 (21a and 21b) and the cutting pedal 22 (22a and 22b) with the right foot.

  The base portion 2a on which the plurality of pedals 20 are arranged is movable in the horizontal direction. Specifically, the base portion 2a is connected to the base 7 of the remote control device 100 by slide bearings on both sides in the width direction (X direction), and the operation pedal portion 2 is in the depth direction (front-back direction, Y direction). It can be moved by sliding to. The movement of the operation pedal portion 2 in the depth direction can be performed electrically by a driving device such as a motor provided in the base 7 of the remote operation device 100. As a result, the position of the pedal 20 can be adjusted according to the operating posture, physique, or preference of the operator O.

  Here, in the first embodiment, the number of sensors 26 that detect the presence of a foot is greater than the number of pedals 20 that are operated downward. Specifically, seven sensors 26 are provided. Further, there are provided six pedals 20 (coagulation pedals 21a and 21b, disconnection pedals 22a and 22b, a camera pedal 23, and a clutch pedal 24) which are operated by pushing downward. That is, the number of sensors that detect the presence of the foot that operates the two coagulation pedals 21 and the two cutting pedals 22 is five.

  In the first embodiment, a plurality of sensors 26 used for detecting the foot to be operated are provided in the vicinity of one pedal 20 among the plurality of pedals 20. It is determined whether or not one of the pedals 20 is operating or is about to be operated. Specifically, when the control unit 61 receives detection information from a plurality of sensors 26 arranged in the vicinity of a certain pedal 20 among the plurality of pedals 20, the foot that operates the certain pedal 20 is operated. Determined to exist. Specifically, when the control unit 61 receives detection information from a plurality of sensors 26 arranged in the vicinity of the pedal 20 (disconnection pedal 22a, coagulation pedal 21a, disconnection pedal 22b, coagulation pedal 21a), the pedal 20 is controlled. It is determined that there is a foot that operates (the cutting pedal 22a, the coagulation pedal 21a, the cutting pedal 22b, the coagulation pedal 21a). In addition, the control unit 61 determines whether there is a foot that operates one certain pedal 20 (first pedal (coagulation pedal 21 and cutting pedal 22)) and one certain pedal 20 (first pedal (coagulation pedal 21 and cutting pedal 22)). For both the determination of the presence of the foot operating the pedal 20 adjacent to the cutting pedal 22)), the detection from a sensor 26 arranged between a pedal 20 and a pedal 20 adjacent to the pedal 20. Use information. Specifically, the control unit 61 disconnects the coagulation pedal 21b from both the determination of the presence of the foot operating the coagulation pedal 21b and the determination of the presence of the foot operating the disconnection pedal 22b adjacent to the coagulation pedal 21b. The detection information from the sensor 26b arranged between the pedal 22b and the pedal 22b is used. In addition, the control unit 61 determines that the cutting pedal 22b and the coagulation pedal 21a are included in both the determination of the presence of the foot operating the cutting pedal 22b and the determination of the presence of the foot operating the coagulation pedal 21a adjacent to the cutting pedal 22b. The detection information from the sensor 26c arranged between the two is used. In addition, the control unit 61 determines the presence of the foot that operates the coagulation pedal 21a and the presence of the foot that operates the cutting pedal 22a adjacent to the coagulation pedal 21a to determine whether the coagulation pedal 21a and the cutting pedal 22a are present. The detection information from the sensor 26d arranged between the two is used.

  Accordingly, the presence of the foot approaching the pedal 20 (the first pedal (the coagulation pedal 21 and the cutting pedal 22)) approaching a certain operation target can be detected by using the plurality of sensors 26, so that the foot of the operator O can be detected. It is possible to accurately specify the pedal 20 that has approached. As a result, it is possible to improve the accuracy of detecting the presence of the foot operating the pedal 20 to be operated among the plurality of pedals 20.

  Further, in the first embodiment, at least one sensor 26 used for detecting the operated foot is provided near each of the plurality of pedals 20. As a result, the presence of the approaching foot can be detected for all the pedals 20. In addition, one sensor 26 is used commonly for a plurality of pedals 20 (first pedal (coagulation pedal 21 and cutting pedal 22)) to detect a foot to be operated. That is, at least one sensor 26 of the plurality of sensors 26 includes one pedal 20 (first pedal (coagulation pedal 21 and disconnection pedal 22)) of the plurality of pedals 20 and a pedal 20 adjacent thereto. It is located in between. Specifically, a certain sensor 26 (light emitting-light receiving type) arranged between the center of the tip side (Y1 side) of one pedal 20 and the center of the tip side (Y1 side) of the pedal 20 adjacent thereto. In the case of a sensor, the linear light emitted from the light emitting unit) is used to detect the presence of a foot operating each of the pedals 20 on both sides. As a result, it is possible to suppress an increase in the number of the sensors 26, so that it is possible to reduce the number of parts and simplify the device configuration.

  In order to simplify the description, in the present specification, the sensor 26 is provided between the central part of the tip side (Y1 side) of a certain pedal 20 and the central part of the tip side (Y1 side) of the pedal 20 adjacent thereto. The configuration in which (the linear light emitted from the light emitting unit in the case of the light emitting-light receiving sensor) is arranged is simply expressed as "the sensor is arranged between a certain pedal and a pedal adjacent to this pedal".

  Then, in the present specification, the sensor 26 arranged at the central portion of the tip end side (Y1 side) of a certain pedal 20 (in the case of the light emitting-light receiving type sensor, the linear light emitted from the light emitting portion passes through the central portion). , And a sensor existing between a pedal and a pedal adjacent to the pedal is defined as “a sensor arranged in the vicinity of a pedal”.

  Further, one sensor 26 of the plurality of sensors 26 arranged in the vicinity of one certain pedal 20 is a pedal 20 adjacent to one certain pedal 20 (first pedal (coagulation pedal 21 and disconnection pedal 22)). It is placed between and. That is, the plurality of sensors 26 arranged in the vicinity of the pedal 20 (disconnection pedal 22a, coagulation pedal 21a, disconnection pedal 22b, coagulation pedal 21a) includes the pedals 20 (disconnection pedal 22a, coagulation pedal 21a, disconnection pedal 22b, coagulation pedal 22a 21a) on both sides in the width direction (X direction). Then, the control unit 61 determines the presence of the foot operating the adjacent pedal 20 by using the detection information by the sensor 26 arranged between the certain pedal 20 and the adjacent pedal 20. That is, the control unit 61 determines that one pedal 20 is present in both the determination of the presence of the foot operating the certain pedal 20 and the determination of the presence of the foot operating the pedal 20 adjacent to the certain pedal 20. The detection information from the sensor 26 arranged between one pedal 20 and the adjacent pedal 20 is used.

  Further, in the first embodiment, at least one pedal 20 of the plurality of pedals 20 detects the foot to be operated using the plurality of sensors 26, and at least one pedal 20 of the plurality of pedals 20 is operated. The moving foot is detected using a single sensor 26. As a result, it is possible to suppress an increase in the number of the sensors 26, so that it is possible to reduce the number of parts and simplify the device configuration.

  Further, when the distance between the adjacent pedals 20 is equal to or larger than the predetermined distance, the single sensor 26 is arranged in the vicinity of the pedal 20, and when the distance between the adjacent pedals 20 is less than the predetermined distance, A plurality of sensors 26 may be arranged near the pedal 20. That is, when the distance between the adjacent pedals 20 is equal to or greater than the predetermined distance, the control unit 61 determines the presence of the foot operating the pedals 20 by using the detection information from the single sensor 26. Further, when the distance between the adjacent pedals 20 is less than the predetermined distance, the control unit 61 determines the presence of the foot operating the pedals 20 by using the detection information from the plurality of sensors 26.

  The predetermined distance from the adjacent pedal can be set to 30 mm or more and 40 mm or less. For example, two sensors are arranged near the pedal 20 whose distance from the adjacent pedal is less than 35 mm, and only one sensor is arranged near the pedal 20 whose distance from the adjacent pedal is 35 mm or more. As specific dimensions, for example, the width dimension of the operation pedal portion 2 is about 640 mm, d3 is about 26 mm, and d4 is about 48 mm.

  Accordingly, for the pedal 20 where the distance between the pedals 20 is small and the pedal 20 to be operated is difficult to discriminate, the pedal 20 to be operated can be accurately discriminated by using the plurality of sensors 26. Further, since a single sensor 26 is used for the pedal 20 in which the distance between the pedals 20 is large and the pedal 20 to be operated is easily discriminated, it is possible to effectively suppress an increase in the number of the sensors 26. You can

  Specifically, the distance between the cutting pedal 22a and the coagulation pedal 21a, the distance between the coagulation pedal 21a and the cutting pedal 22ba, and the distance between the cutting pedal 22b and the coagulation pedal 21b are less than a predetermined distance. The distance is d3. That is, the distance between the first pedal (coagulation pedal 21, cutting pedal 22) and the adjacent pedal 20 is less than the predetermined distance. The distance between the camera pedal 23 and the clutch pedal 24 is a distance d4 that is equal to or greater than a predetermined distance. That is, the distance between the second pedal (the camera pedal 23 and the clutch pedal 24) and the adjacent pedal 20 is equal to or greater than the predetermined distance. That is, one sensor 26 (sensor 26f, sensor 26g) is provided near the second pedal (camera pedal 23, clutch pedal 24).

  The presence of a foot approaching the coagulation pedal 21b is detected by the sensors 26a and 26b. That is, when the foot is detected by both the sensors 26a and 26b, the controller 61 determines that the pedal 20 to be operated is the coagulation pedal 21b. Further, the presence of a foot approaching the cutting pedal 22b is detected by the sensors 26b and 26c. That is, when the foot is detected by both the sensors 26b and 26c, the control unit 61 determines that the pedal 20 to be operated is the disconnection pedal 22b.

  Further, the presence of a foot approaching the coagulation pedal 21a is detected by the sensors 26c and 26d. That is, when the foot is detected by both the sensors 26c and 26d, the controller 61 determines that the pedal 20 to be operated is the coagulation pedal 21a. Further, the presence of a foot approaching the cutting pedal 22a is detected by the sensors 26d and 26e. That is, when the foot is detected by both the sensors 26d and 26e, the controller 61 determines that the pedal 20 to be operated is the disconnection pedal 22a.

  Further, the sensor 26f detects the presence of a foot approaching the clutch pedal 24. That is, when the foot is detected by the one sensor 26f, the control unit 61 determines that the pedal 20 to be operated is the clutch pedal 24 (second pedal). Further, the sensor 26g detects the presence of a foot approaching the camera pedal 23. That is, when one sensor 26g detects a foot, the control unit 61 determines that the pedal 20 to be operated is the camera pedal 23 (second pedal).

  The light emitting unit 261 includes a light emitting element such as an LED. The light emitting unit 261 is configured to emit invisible light such as visible light or infrared light. The light receiving section 262 includes a light receiving element. The corresponding light emitting unit 261 and light receiving unit 262 are arranged along the Y direction in a plan view. That is, as shown by the broken lines in FIGS. 4 to 6, the light from the light emitting unit 261 is mainly radiated along the Y direction in a plan view. Further, the corresponding light emitting units 261 and the light receiving units 262 are arranged so that the arrangement directions thereof are parallel to each other in plan view. As a result, the width (length in the X direction) of the operation pedal portion 2 for disposing the sensor 26 on the outer side is greater than that in the case where the corresponding light emitting portion 261 and light receiving portion 262 of the sensor 26 are arranged in a fan shape. Does not have to be large.

  Further, the light emitting unit 261 is configured to emit light obliquely downward.

  An example of allocation of the coagulation pedal 21 (21a and 21b) and the disconnection pedal 22 (22a and 22b) of the operation pedal unit 2 will be described with reference to FIG. 7. The coagulation pedal 21a and the cutting pedal 22a are used in one set, and the coagulation pedal 21b and the cutting pedal 22b are used in one set. Here, the surgical site can be cut or coagulated by one forceps (for example, grasper). When cutting and coagulating with one forceps, a high voltage is applied to the cutting and a lower voltage is applied to the coagulation than in the case of cutting. That is, by selecting and using the coagulation pedal 21a (21b) and the cutting pedal 22a (22b), the surgical site can be coagulated and cut. Further, even if cutting and coagulation can be performed with a grasper or the like, a sealing device for coagulation may be used exclusively or together. This is because the sealing device often has additional functions such as automatically ending the power supply when the coagulation is completed.

  In the example shown in FIG. 7, the bipolar forceps F1, the monopolar forceps F2, the sealing device F3, and the endoscope 201b as the instrument 201a are attached to the four surgical manipulators 201. The positional relationship between the four surgical manipulators 201 is recognized by the position detector provided in each manipulator. The positional relationship between the left and right of each manipulator is recognized from the position viewed from the platform 203. In FIG. 7A, when viewed from the camera arm 201B to which the endoscope 201b is attached, the monopolar forceps F2 is arranged on the left side, and the bipolar forceps F1 and the sealing device F3 are arranged on the right side as viewed from the camera arm 201B in order from the left. Has been done. As an assignment between the coagulation pedal 21 (21a and 21b) and the cutting pedal 22 (22a and 22b), first, the leftmost instrument arm of the instrument arm 201A to which the instrument 201a is attached. 201A is assigned to the left foot pedal (coagulation pedal 21a and cutting pedal 22a), and the instrument arm 201A on the right is assigned to the right foot pedal (coagulation pedal 21b and cutting pedal 22b). That is, in FIG. 7A, the monopolar forceps F2 is assigned to the left foot pedal (coagulation pedal 21a and cutting pedal 22a). Further, the bipolar forceps F1 is assigned to the right foot pedal (coagulation pedal 21b and cutting pedal 22b). When only two instruments 201a are attached, they are assigned to the left foot pedal and the right foot pedal, respectively, in order from the leftmost instrument arm 201A when viewed from the camera arm 201B. When only one instrument 201a is attached, it is assigned to the left foot pedal.

  In FIG. 7B, the assistant (for example, a nurse) replaces the bipolar forceps F1 with the monopolar forceps F2. In this case, the type of the instrument 201a is specified by the attachment of the instrument 201a to the instrument arm 201A. For example, information such as the model number of the device may be stored in the IC of the interface. Then, the bipolar forceps F1 is assigned to the left foot pedal (coagulation pedal 21a and cutting pedal 22a). Further, the monopolar forceps F2 is assigned to the right foot pedal (coagulation pedal 21b and cutting pedal 22b).

  In FIG. 7C, the assistant (for example, a nurse) replaces the monopolar forceps F2 and the sealing device F3. The type of the instrument 201a is specified by the attachment to the instrument arm 201A. Then, the bipolar forceps F1 is continuously assigned to the left foot pedal (coagulation pedal 21a and cutting pedal 22a). Further, the sealing device F3 is assigned to the right foot pedal (coagulation pedal 21b and cutting pedal 22b).

  In FIG. 7D, the side pedal 25 switches the activated instrument arm 201A of the two instrument arms 201A on the right side. That is, the instrument arm 201A operated by the operation handle 1 is switched. As a result, the left operation handle 1 operates the instrument arm 201A to which the bipolar forceps F1 is attached, and the right operation handle 1 operates the instrument arm 201A to which the monopolar forceps F2 is attached. It The bipolar forceps F1 is continuously assigned to the left foot pedal (coagulation pedal 21a and cutting pedal 22a). Further, the monopolar forceps F2 is assigned to the right foot pedal (coagulation pedal 21b and cutting pedal 22b).

  In FIG. 7 (E), the side pedal 25 switches the instrument arm 201A to be activated among the two instrument arms 201A on the right side. That is, the instrument arm 201A operated by the operation handle 1 is switched. As a result, the left operation handle 1 operates the instrument arm 201A to which the bipolar forceps F1 is attached, and the right operation handle 1 operates the instrument arm 201A to which the sealing device F3 is attached. .. The bipolar forceps F1 is continuously assigned to the left foot pedal (coagulation pedal 21a and cutting pedal 22a). Further, the sealing device F3 is assigned to the right foot pedal (coagulation pedal 21b and cutting pedal 22b).

  Although a simple grasper that does not apply electricity may be used, which is mainly used when a strong gripping force is required, the coagulation pedal 21 (21a 21b) and the cutting pedal 22 (22a and 22b) are not operated, the coagulation pedal 21 and the cutting pedal 22 are not assigned. That is, when allocating the coagulation pedal 21 (21a and 21b) and the cutting pedal 22 (22a and 22b), the instrument arm 201A that holds the instrument 201a to which electricity is not applied is set to be ignored. Just keep it.

  The left foot pedal (coagulation pedal 21a and cutting pedal 22a) and the right foot pedal (coagulation pedal 21b and cutting pedal 22b) may be assigned by another method (rule). For example, a foot pedal may be assigned to each of the left and right instrument arms 201A of the camera arm 201B. For example, one instrument arm 201A on the left side of the camera arm 201B is assigned to the left foot pedal (coagulation pedal 21a and cutting pedal 22a), and the left side of the two instrument arms 201A on the right side of the camera arm 201B. Alternatively, the instrument arm 201A in FIG. 2 may be assigned to the right foot pedal (coagulation pedal 21b and cutting pedal 22b).

  When the instrument 201a and the endoscope 201b are attached to the surgical manipulator 201 so that the two instrument arms 201A exist on the left side of the camera arm 201B, the two instruments on the left side of the camera arm 201B Of the arms 201A, the left instrument arm 201A is assigned to the left foot pedal (coagulation pedal 21a and cutting pedal 22a), and one instrument arm 201A on the right side of the camera arm 201B is connected to the right foot pedal (coagulation pedal). It may be assigned to the pedal 21b and the disconnect pedal 22b). In this case, by detecting that there are two instrument arms 201A on the left side of the camera arm 201B and only one instrument arm 201A on the right side of the camera arm 201B, switching is performed by the side pedal 25. It is preferable to set a rule that the instrument arms 201A to be set are automatically set so as to be the two instrument arms 201A existing on the left side of the camera arm 201B.

  When there are a plurality of instrument arms 201A on both the left and right sides of the camera arm 201B, one side (for example, the right surgical manipulator 201 with a large number of dominant hands) is set as a switching target by the side pedal 25, and an additional Switching targets (a plurality of instrument arms 201A on the right side of the camera arm 201B or a plurality of instrument arms on the left side of the camera arm 201B by an operator (for example, a touch panel (operation unit 53) provided on the armrest 5)). 201A) is preferably changeable. Alternatively, a second lateral pedal (not shown) is provided on the further right side of the coagulation pedal 21b, and the plurality of instrument arms 201A on the left side of the camera arm 201B are switched by the lateral pedal 25, and the right side of the camera arm 201B is switched. The plurality of instrument arms 201A may be switched by the second lateral pedal.

  Furthermore, although the example in which the camera arm 201B is one of the inner sides of the plurality of surgical manipulators 201 has been described above, the camera arm 201B may be located at the end of the plurality of surgical manipulators 201. Also in this case, according to a specific rule, for example, the left foot pedal (coagulation pedal 21a and cutting pedal 22a) is assigned to the leftmost instrument arm 201A, and the right foot is assigned to the second instrument arm 201A from the left. Although the pedals (coagulation pedal 21b and disconnection pedal 22b) are assigned, the second instrument arm 201A from the left and the third instrument arm 201A from the left are set to be switched by the side pedals 25. In the same manner as described above, it is possible to change the target of switching by the side pedal 25 with the additional operator, for example, the leftmost instrument arm 201A and the second instrument arm 201A from the left. It is preferable to keep it.

  Further, when it is detected that the camera arm 201B is any one of the insides of the plurality of surgical manipulators 201, the instrument arm 201A located near the camera arm 201B is preferentially assigned to the foot pedal. You can make it a rule. For example, in FIG. 7A, one instrument arm 201A exists on the left side of the camera arm 201B, and two instrument arms 201A exist on the right side of the camera arm 201B. One instrument arm 201A on the left side of the camera arm 201B is assigned to the left foot pedal (coagulation pedal 21a and cutting pedal 22a), and the camera arm 201B out of the two instrument arms 201A on the right side of the camera arm 201B. The instrument arm 201A located at a position close to may be assigned to the right foot pedal (coagulation pedal 21b and cutting pedal 22b). When two instrument arms 201A are present on the left side of the camera arm 201B, one of the two instrument arms 201A on the left side of the camera arm 201B is closer to the camera arm 201B (right side). The instrument arm 201A is assigned to the left foot pedal (coagulation pedal 21a and cutting pedal 22a), and one instrument arm 201A on the right side of the camera arm 201B is connected to the right foot pedal (coagulation pedal 21b and cutting pedal 22b). Assign to.

  In the above, the endoscope 201b is attached to the surgical manipulator 201 attached to the platform 203, and the allocation rule is set by recognizing the position of the camera arm 201B, but the camera arm 201B is independent of the platform 203. Even when provided, the above rules can be used by appropriately recognizing the positional relationship between the camera arm 201B and the plurality of instrument arms 201A by calibration using the world coordinate system. In this case, with respect to the left-right relationship between the surgical manipulators 201, it is necessary to determine the reference from which viewpoint the operation manipulator 201 is viewed by default or by setting the operator O.

  As described above, if the surgical manipulators 201 to be operated on the left and right operation handles 1 are assigned according to rules, complicated detection such as detecting which manipulator the left and right operation handles 1 are operating is performed. It is possible to simply assign the two pairs of foot pedals to the plurality of instrument arms 201A without providing any means.

  In order to ensure that the operator O can understand the assignment relationship between the left and right operation handles 1 and the two pairs of foot pedals for the plurality of instrument arms 201A, at least the endoscope described below is used. It is preferable to display the relationship of assignment between the operation handle 1 and the foot pedal on the display unit 3 that displays the image from 201b.

  The display unit 3 is capable of displaying 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. The scope type display unit 3a is, for example, a looking-in 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 looking-in type like a display of an ordinary personal computer. The scope-type display unit 3a and the non-scope-type display unit 3b are configured so that they can be selectively attached to the remote control device 100. Specifically, the scope type display unit 3a includes a display 31a, a gripping unit 32, and a mounting unit 33, as shown in FIG. Moreover, the non-scope type display unit 3b includes a display 31b, a gripping unit 32, and a mounting unit 33, as shown in FIG. The mounting portion 33 of the scope-type display portion 3a or the non-scope-type display portion 3b is configured to be attached to the mounted portion 41 of the display portion supporting arm 4 of the remote control 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. Thereby, either the immersive type remote control device or the open type remote control device can be selected, so that it is possible to provide the remote control device 100 having versatility with respect to the display unit 3.

  Moreover, since the operation usually takes several hours, the operator may feel lonely when working for a long time with the 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 the feeling of performing surgery as a team.

  Further, if the remote control device has versatility and expandability with respect to the display unit, even if the display unit is broken or damaged, only the display unit needs to be repaired, and replacement of the entire device is unnecessary. Further, there is also an advantage that the display unit can be upgraded without replacing the entire device each time a display unit with high definition and high image quality is developed. The operator O also has the advantage of being able to select a display unit of a desired manufacturer / specification (size, shape, operation panel, etc.).

  The display unit 3 also includes a terminal 34, as shown in FIG. The terminal 34 is, for example, 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, or the like capable of transmitting video. including. The terminal 34 is connected to the control device 6. That is, by connecting the connection line to the terminal 34, the image information is transmitted from the control device 6 to the display unit 3. Further, by removing the connection line from the terminal 34, the display unit 3 can be removed from the remote control device 100.

  When the scope-type display unit 3a is attached, the 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, the 3D image captured by the endoscope 201b provided in the patient-side system 200 is displayed. In addition, 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 also 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 display for the left eye and a display for the right eye. Further, by looking into the display 31a, the display for the right eye cannot be seen by the left eye, and the display for the left eye cannot be seen by the right eye. The display 31a is composed of a liquid crystal display, an organic EL display, or the like. Moreover, you may use a projection type display for the display 31a.

  The non-scope type display unit 3b is an open type display unit that can be viewed 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, but considering the balance between ensuring sufficient visibility of the operative field and easy replacement, it is about 15 inches to 35 inches. Is appropriate. The display 31b is composed of a liquid crystal display, an organic EL display, or the like. A projection type display may be used as the display 31b. Since the operator O stereoscopically recognizes the image captured by the endoscope 201b, a known stereoscopic method such as a method using polarized glass or a method using active shutter glass may be applied.

  Further, when the sensor 26 detects the presence of the foot of the operator O, the foot presence detection information is displayed on the foot pedal arrangement map displayed on the display unit 3. For example, in the foot pedal layout map, the six downward pedals 20 are arranged in the same order as in FIG. 5 (from the left in the X direction, the camera pedal 23, the clutch pedal 24, the disconnection pedal 22a, the coagulation pedal 21a, the disconnection pedal 22b, and the coagulation pedal 21b. ) Is displayed, and when the presence of a foot is detected, the color is changed, the color intensity is changed, and blinking is performed, so that highlighting is performed. The function (coagulation, disconnection, camera, clutch) of the pedal 20 to be operated may be displayed on the display unit 3 (for example, on the foot pedal layout map). Further, the information of the end effector operated by the corresponding pedal 20 may be displayed on the display unit 3, and the information of the end effector may be highlighted when the presence of a foot is detected. Further, the display unit 3 displays information on the surgical manipulator 201 that holds the corresponding forceps (for example, the number of the surgical manipulator 201). Further, for example, in the case of the pedal 20 for the right-hand operation handle 1, information on the end effector and the surgical manipulator is displayed on the right side of the display unit 3, and in the case of the pedal 20 for the left-hand operation handle 1, the left side of the display unit 3. Information of the end effector and the surgical manipulator may be displayed in.

  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 by 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 unit 3 so as not to interfere with the visual recognition of the display 31a (31b). The gripping part 32 can be gripped with one hand, but a plurality of gripping parts 32 may be provided. For example, as shown in FIG. 2, the grips 32 may be provided on both sides of the display unit 3 so that the operator O sitting on the front can grip the right hand or the left hand.

  The mounting portion 33 is mounted on the mounted portion 41 of the display supporting arm 4. That is, the attached portion 41 is selectively detachably attached to the scope-type display portion 3a and the non-scope-type display portion 3b. For example, the mounting portion 33 includes an engaging portion 331 as in the first example shown in FIG. The attached portion 41 also includes an unlock button 411 and an engaging portion 412. As shown in FIG. 12 (A), 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 with each other, so that the mounted portion 41 of the display support arm 4 is attached to the mounting portion 41. On the other hand, the mounting portion 33 is fixed. As a result, the display unit 3 is fixed and supported by the display unit support arm 4. That is, the engagement portion 331 and the engagement portion 412 form a lock mechanism for fixing the display unit 3 (the scope-type display unit 3a or the non-scope-type display unit 3b).

  As shown in FIG. 12B, when the lock release button 411 is pressed downward, the engagement portion 412 moves, and the engagement between the engagement portion 331 and the engagement portion 412 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 lock release button 411 functions as a lock release mechanism that releases the fixed state by the lock mechanism configured by the engagement portion 331 and the engagement portion 412. Further, the lock release mechanism is configured to release the fixed state by the lock mechanism by the action of the force downward in the vertical direction. Accordingly, the lock release mechanism can easily release the fixed state by the lock mechanism.

  As shown in FIG. 12 (C), 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 vertically upward while the lock release mechanism is acting vertically downward. Be done. As a result, since the display unit 3 is removed while exerting a force in the opposite direction of the vertical downward operation and the vertical upward operation of the operating unit, 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 and removed, the display unit 3 can be removed without interfering with the operation handle 1 located below.

  The lock mechanism and the lock release mechanism may have other configurations. For example, the second example shown in FIG. 13 may be used. The mounting portion 33 includes an engaging portion 332 as in the second example shown in FIG. 13. The mounted portion 41 also includes an engaging portion 413. As shown in FIG. 13A, 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 with each other, so that the mounted portion 41 of the display unit supporting arm 4 is attached to the mounting portion 41. On the other hand, the mounting portion 33 is fixed. Specifically, the engaging portion 332 sandwiches and holds the engaging portion 413 to engage with each other. As a result, the display unit 3 is fixed and supported by the display unit support arm 4. That is, the engagement portion 332 and the engagement portion 413 form a lock mechanism for fixing the display portion 3 (the scope-type display portion 3a or the non-scope-type display portion 3b).

  As shown in FIG. 13B, 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. 13C, 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 vertically upward when the fixed state is released.

  The lock mechanism and the lock release mechanism may have other configurations. For example, the third example shown in FIG. 14 may be used. The mounting portion 33 includes a notch 333 as in the third example shown in FIG. The attached portion 41 also includes a lock release button 414, a fitting portion 415, and an engaging portion 416. As shown in FIG. 14A, the lock release button 414 is urged upward in the vertical direction by a spring or the like, and the engagement portion 416 is urged in a direction away from the fitting portion 415 in the horizontal direction, so that the lock release button 414 is released. The vertical operation and the horizontal operation of the engaging portion 416 are linked by gears 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 with each other, and the mounting portion 33 is fixed to the mounted portion 41 of the display unit support arm 4. As a result, the display unit 3 is fixed and supported by the display unit support arm 4. That is, the notch 333 and the engaging portion 416 constitute a lock mechanism for fixing the display unit 3 (the scope-type display unit 3a or the non-scope-type display unit 3b).

  As shown in FIG. 14B, when the unlock 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 fits into the fitting portion 415. As a result, 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 lock release button 414 functions as a lock release mechanism that releases the fixed state by the lock mechanism configured by the notch 333 and the engagement portion 416. Further, the lock release mechanism is configured to release the fixed state by the lock mechanism by the action of the force downward in the vertical direction.

  As shown in FIG. 14C, 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 vertically upward when the fixed state is released.

  Since the engaging portion 416 has an inclined surface whose lower dimension is larger than its upper dimension, when the mounting portion 33 is pushed vertically downward with respect to the mounted portion 41, the mounting portion 33 engages. When the engaging portion 416 is brought into contact with the inclined surface of the portion 416 to push the engaging portion 416 toward the fitting portion 415 in the horizontal direction and moves to a predetermined position, the engaging portion 416 fits into the notch 333 and is locked. ..

  The display support arm 4 is configured to support the display 3, as shown in FIG. The display part support arm 4 includes a mounted part 41 and arm parts 42 and 43. The display unit support arm 4 is provided with the mounted portion 41 at one end and is supported by the column 44 at the other end. The pillar 44 is fixed to the support portion 91 of the support mechanism 9. That is, the display section 3 is supported by the support section 91. The display part support arm 4 supports the mounted part 41 so as to be rotatable about vertical rotation axes A1, A2, and A3. That is, the mounted portion 41 is supported by a support member having a vertical rotating shaft so that the angle can be adjusted with three degrees of freedom. Specifically, the arm portion 43 is supported rotatably in the horizontal direction with respect to the column 44 about the rotation axis A1. The arm portion 42 is supported rotatably in the horizontal direction with respect to the arm portion 43 about the rotation axis A2. The mounted portion 41 is supported rotatably in the horizontal direction with respect to the arm portion 42 about a rotation axis A3. As a result, the display unit 3 attached to the attached portion 41 can be moved in the horizontal direction, so that the display unit 3 can be arranged at a position desired by the operator O.

  When the scope-type display unit 3a is attached to the remote control device 100, as shown in FIG. 2, the scope-type display unit 3a is tilted with respect to a horizontal rotation axis B1 that is substantially orthogonal to the rotation axis A3. It is configured to rotate. When the non-scope type display unit 3b is attached to the remote control device 100, as shown in FIG. 11, the non-scope type display unit 3b has a horizontal rotation axis B2 substantially orthogonal to the rotation axis A3. It is configured to tilt and rotate. Thereby, the elevation angle and the depression angle of the display unit 3 mounted on the mounted portion 41 can be adjusted. The posture of the display unit support arm 4 may be manually changed by the operator O or another person, or the posture may be changed by providing a drive unit including a motor, an encoder and a brake to control the operation. Good.

  The armrest 5 is configured to support the arm of the operator O. The armrest 5 includes an arm support portion 51, a pair of connection portions 52, and an operation portion 53. The arm support portion 51 is arranged on the front side (Y1 direction side) of the operation handle 1 and is configured to support the arm of the operator O. As a result, the arm of the operator O can be stabilized, and the operation of the operation handle 1 by the operator O can be stably performed. That is, even when the end effector is finely operated, the operator O can perform an operation while leaning the armrest 5 against the elbow or the like for stabilization. Further, even if the operation is performed for a long time, the burden on the operator O can be reduced. The arm support portion 51 is formed so as to extend in the X direction. A pair of connecting portions 52 is provided. The pair of connecting portions 52 are provided at both ends of the arm supporting portion 51 so as to sandwich the arm supporting portion 51 in the X direction. The connecting portion 52 is configured to support the arm supporting portion 51. The connecting portion 52 is formed so as to extend in the Y direction. That is, the end of the connecting portion 52 in the Y1 direction is connected to the arm supporting portion 51. Further, the connecting portion 52 is connected to the supporting portion 91 of the supporting mechanism 9 at the end in the Y2 direction. That is, the armrest 5 is supported by the support mechanism 9. Further, the connecting portion 52 is formed so as to extend upward along the front side (Y1 direction side) from the back side (Y2 direction side). As a result, the vertical position of the side of the connecting portion 52 connected to the base 7 can be lowered, so that the armrest 5 can be stabilized. The operation unit 53 can operate the settings of the remote operation device 100. For example, the operation unit 53 can operate the attitude of the remote control device 100. In this case, the operation unit 53 functions as the posture operation unit 8.

  As shown in FIG. 3, the control device 6 includes, for example, a control unit 61 having a computing unit such as a CPU, a storage unit 62 having memories 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 uses the operation mode command input by the operation handle 1 as the 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 the command is an operation mode command to be executed by 201b. When the control unit 61 determines that the motion mode command input to the operation handle 1 is the motion mode command to be executed by the instrument 201a, the control unit 61 transmits the motion mode command to the instrument arm 201A. .. As a result, the instrument arm 201A is driven, and the operation controls the operation of the instrument 201a attached to the instrument arm 201A.

  When the control unit 61 determines that the operation mode command input to the operation handle 1 is the operation mode command to be executed by the endoscope 201b, the control unit 61 transmits the operation mode command to the camera arm 201B. As a result, the camera arm 201B is driven, and the operation controls the operation of the endoscope 201b attached to the camera arm 201B.

  Further, the control unit 61 receives the detection information of the presence of the operator O's foot from the sensor 26 and determines whether or not the operator O's foot is present. In addition, when it is determined that the operator O's foot is present, the control unit 61 controls the display unit 3 to display a corresponding display.

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

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

  As shown in FIGS. 8 and 9, the remote control device 100 is configured so that the position of the operation handle 1 can be moved in the vertical direction. Specifically, the posture operation unit 8 accepts an operation for moving the position of the operation handle 1 in the vertical direction. Then, based on the operation received by the posture operation unit 8, the support handle 9 moves the operation handle 1 in the vertical direction.

  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. Further, the support section 91 supports the display section 3 via the display section 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. The drive unit 92 of the support mechanism 9 may be driven by air pressure or hydraulic pressure. In addition, the armrest 5 may be rotated with respect to the support mechanism 9 to be adjusted in position. For example, the armrest 5 may rotate about a rotation axis line along the X direction.

  The support mechanism 9 holds the operation handle 1 by arranging 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 where the remote operation device 100 is installed. With the first mode (see FIG. 8), the operating handle 1 located in the neutral position A0 of the operating region A is located at a height position H2 that is 48 cm or more lower than the height position H1 and the operating handle 1 is held. The second mode (see FIG. 9) is configured to be transitable. Accordingly, by positioning the operation handle 1 located at the neutral position A0 of the operation area A at the height position H1 of 85 cm or more from the floor surface, the operator O can operate the operation handle 1 in a standing state. 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 lower than the height position H1 by 48 cm or more, the operation handle 1 is operated while the operator O is sitting. be able to. This allows the operator O to operate the remote control device 100 in a desired posture. Moreover, since the operation handle 1 is supported by the support mechanism 9, the operator O does not need to support the operation handle 1. As a result, it is possible to prevent the burden on the operator O from increasing. In addition, the armrest 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.

  In addition, the support mechanism 9 holds the operation handle 1 so that the operation area A of the operation handle 1 fits in a clean area set at a predetermined height or more from the floor where the remote operation device 100 is installed. (See FIG. 8) and a second mode (see FIG. 9) in which the operating handle 1 is held so that at least a part of the operating region A of the operating handle 1 is located in a region below the clean region. It is configured to be possible.

  Here, in the operating room, a clean operation is performed in order to prevent the portion incised by the operation and the medical device from being contaminated by pathogenic bacteria, foreign substances, and the like. In this clean operation, a clean area and a contaminated area other than the clean area are set. Then, an 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 excluded from the clean area. This area is, for example, an area up to a height of about 70 cm from the floor surface. That is, as the clean area, for example, an area having a height of about 70 cm or more from the floor surface where the remote control device 100 is installed is set. During the operation, the members of the operation team including the operator O consider that only the sterilized objects are located in the clean area, and when moving the 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 or her hands in the contaminated area, a hand sterilization process is performed prior to direct contact with objects located in the clean area. The operation handle 1 is treated as not clean, and even in a clean area, the operator O does not access the patient P while operating the operation handle 1 unless sterilization or drape is taken. ..

  As a result, the operator O puts his / her hand out of the clean area by positioning the operation handle 1 so that the operation area A of the operation handle 1 fits in the clean area set above the predetermined height from the floor surface. It is possible to operate the operation handle 1 without using it. Thereby, for example, if the operation handle 1 is treated cleanly, the operator's O hand 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 the area below the clean area, the operation handle 1 is held at a low position where the operator O is sitting. It can be operated. This allows the operator O to operate the remote control device 100 in a desired posture. Moreover, since the operation handle 1 is supported by the support mechanism 9, the operator O does not need to support the operation handle 1. As a result, it is possible to prevent the burden on the operator O from increasing.

  In addition, the support mechanism 9 includes a first mode (see FIG. 8) for holding the operation handle 1 at a position adapted for the operator O to operate the operation handle 1 in a standing position, and the operation handle 1 operated by the operator O. The second mode (see FIG. 9) in which the operation handle 1 is held at a position adapted to be operated in the sitting position is configured to be transitable. Accordingly, by making the remote control device 100 in the first form, the operator O can operate the operation handle 1 while standing. Moreover, by making the remote control device 100 the second form, the operator O can operate the operation handle 1 while sitting down. This allows the operator O to operate the remote control device 100 in a desired posture. Moreover, since the operation handle 1 is supported by the support mechanism 9, the operator O does not need to support the operation handle 1. As a result, it is possible to prevent the burden on the operator O from increasing.

  Further, the support mechanism 9 is configured to be able to move both the operation handle 1 and the armrest 5 in the vertical direction between the first form and the second form. Specifically, the support mechanism 9 is configured to be able to integrally move both the operation handle 1 and the armrest 5 in the vertical direction between the first form and the second form. As a result, the number of parts can be reduced as compared with the case where the members for moving the operation handle 1 and the armrest 5 in the vertical direction are separately provided, so that the device configuration can be simplified and It is possible to prevent the device from increasing in size. In addition, the support mechanism 9 is configured such that the display unit 3 supported by the display unit support arm 4 is also vertically movable between the first form and the second form. That is, the support mechanism 9 is configured such that the operation handle 1, the armrest 5, and the display unit 3 can be integrally moved 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 the image captured by the endoscope 201b, and in each of the first mode and the second mode, the relative position of the display unit 3 with respect to the operation handle 1. The display unit 3 is supported so that it can be changed. Specifically, the position of the display unit 3 is moved with respect to the operation handle 1 by the display unit support arm 4 supported by the support mechanism 9. As a result, the position of the display unit 3 can be changed with respect to the operation handle 1 according to the physique and posture of the operator O, so that versatility of the display unit 3 can be improved.

  The posture operation unit 8 is configured to receive an operation for vertically moving the operation handle 1, the display unit 3 supported by the display unit support arm 4, and the armrest 5. Further, the posture operation unit 8 is configured to receive an operation for moving the operation pedal unit 2 in the front-rear direction (Y direction). That is, the posture operation unit 8 is configured to receive an operation of deforming the remote control device 100 between the first posture and the second posture.

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

  The support mechanism 9 is configured to vertically move the operation handle 1, the display unit 3 supported by the display unit support arm 4, and the armrest 5. The drive unit 92 of the support mechanism 9 includes, for example, a motor and an encoder, and drives based on a command from the posture operation unit 8. The drive unit 92 is supported by the base 7. The drive unit 92 is arranged near the end of the base 7 in the Y2 direction in the front-rear direction (Y direction), and is provided substantially at the center of the base 7 in the left-right direction (X direction). The operation mechanism 1, the display unit 3 supported by the display unit support arm 4, and the armrest 5 may be independently moved in the vertical direction by the support mechanism 9.

  Further, in the state of the first embodiment, the support mechanism 9 positions the operation handle 1 located at the neutral position A0 of the operation area A at a height position H1 of 99 cm or more from the floor where the remote operation device 100 is installed. Therefore, it is preferable to hold the operation handle 1. Further, in the state of the second embodiment, the support mechanism 9 positions the operation handle 1 located at the neutral position A0 of the operation region A at a height position H2 that is 50 cm or more lower than the height position H1. Is preferably held.

  Further, when the form is changed between the first form and the second form, the operation of the patient side system 200 by the operation handle 1 is disabled. Specifically, when the form is modified 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 done. That is, the control unit 61 does not transmit the operation mode command to the patient side system 200 even when the command is transmitted from the operation handle 1 while the mode is being modified between the first mode and the second mode. .. Thereby, it is possible to prevent the operation of the patient-side system 200 from being operated unintentionally while the operation handle 1 is being deformed between the first form and the second form.

  As shown in FIG. 8, when the remote control device 100 is in the standing position (first position), the operating handle 1 is located at the neutral position A0 with the operator O standing upright with his arms bent at a substantially right angle. The operation handle 1 is set so as to be located at a height position suitable for gripping. Further, the display unit 3 is set to be located at a height position suitable for the operator O standing upright 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 to be at the eye level of the operator O.

  In the operating room, when the area up to the height H of 70 cm from the floor is set as the contaminated area, if the design is based on the human model in ergonomics, the operating handle in the upright adaptation form (first posture) One operation area A can be configured such that the entire operation area A fits in a clean area of 70 cm or more from the floor surface.

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

  As shown in FIG. 9, when the posture of the remote control device 100 is the sitting position (second posture), the operation of the operator O sitting on the chair at the neutral position A0 with his or her arm bent at a substantially right angle The operation handle 1 is set to be located at a height position suitable for gripping the handle 1. Further, the display unit 3 is set to be located at a height position suitable for the operator O sitting on the chair 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 located at the eye level of the operator O. In a long-time operation, the operator O can reduce the accumulated fatigue of the operator O by performing the operation in a sitting position.

  In the operating room, when the area up to the height H of 70 cm from the floor is set as the contaminated area, if the design is based on the human model in ergonomics, the operating handle 1 in the sitting position adaptation form (second posture) The operation area A of is at least partially located in the contaminated area.

  When the posture of the remote control device 100 is 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 control device 100. That is, the operating pedal portion 2 is moved to a position where the foot of the operating pedal portion 2 can be reached when the operator O sitting on the chair touches the operating handle 1. 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 by 350 mm or more in the front-rear direction (Y direction). As a result, the operation pedal portion 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, the measurement data described in "1988 ANTHROPOMETRIC SURVEY OF U.S. ARMY PERSONNEL: METHODS AND SUMMERY STATISTICS (1988)" were 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-Design of control center-Part 4: Workstation" Arrangements and Dimensions in Section 5 specifies the use of human models at the 5th and 95th percentiles.

  The operation area A is defined to be 15 cm above and below the neutral position A0, that is, the size of the operation area A in the height direction is 30 cm. This is defined based on the size in the height direction of the operating region of the surgical instrument and the operating magnification of the operating handle 1, which are set in order to maintain good operability of the surgical instrument during laparoscopic surgery. The size in the height direction of the operating region of the surgical instrument thus set is 30 cm, and the operating magnification of the operating handle 1 is 1/2. Therefore, the size in the height direction of the operation region A, which is guided based on the size in the height direction of the operation region of the surgical instrument and the operation magnification of the operation handle 1, is 30 cm.

  FIG. 10A is a diagram showing the model of the operator O, and is a diagram showing the model of the large operator O1. FIG. 10B is a diagram showing the model of the operator O, and is a diagram showing the model of the small operator O2.

  As shown in FIG. 10 (A), the body data of a German male was used as a model of the large operator O1. Out of 100 randomly selected German male models, the fifth model from the top stands upright (standing position) and bends the arm at a right angle to grip the operating handle 1 located in the neutral position A0 of the operating area A. 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 operating handle 1 is about 703 mm when the operating handle 1 located at the neutral position A0 of the operating region A is bent with the arm bent at a right angle while seated. The lower limit is about 553 mm and the upper limit is about 853 mm.

  As shown in FIG. 10 (B), body data of a Japanese woman was used as a model for the small operator O2. Operation when the fifth model from the bottom among 100 randomly selected models of Japanese women stands upright and the arm is bent at a right angle to grasp the operation handle 1 located at the neutral position A0 of the operation area A 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 is about 643 mm when the arm is bent at a right angle and the operation handle 1 located at the neutral position A0 of the operation region A is gripped while seated. 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 where a plurality of operators O having different physiques can take the standing and sitting postures without problems is as follows. First, the height position of the operation handle 1 located at the neutral position A0 of the operation area A in the standing position adaptive mode (first mode) is set to about 99 cm or more corresponding to the model of the small operator O2 in the standing position. Preferably. As a result, most of the 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 15 cm downward from the neutral position A0, the lower limit of the height position of the operation area A of the operation handle 1 in the standing position adaptive form is 84 cm or more as described above. Is.

  In addition, it is preferable that the height position of the operation handle 1 located at the neutral position A0 in the standing position adaptive mode (first state) is set to 85 cm or more. As a result, 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 adaptive form is 70 cm or more, The operation area A of No. 1 can be accommodated in a clean area. Further, as described above, the lower limit of the height position of the operation area A corresponding to the model of the operator O2 standing upright is about 84 cm. Therefore, the lower limit of the height position of the operation area A should be set to 70 cm. Therefore, a large number of operators O having different physical constitutions can comfortably operate the operation handle 1 while standing.

  Next, the height position of the operation handle 1 located at the neutral position A0 of the operation area A in the sitting position adaptive form (second state) should be set to about 64 cm or more corresponding to the model of the small operator O2 in the sitting position. Is preferred. This allows most of the operator O to comfortably operate the operation handle 1 in the sitting position.

  Next, the displacement (adjustment width) of the height position of the operation handle 1 when the remote control device 100 is transited between the standing position adaptive form and the sitting position adaptive form is the model of the standing small operator O2. The difference between the height position of the operation handle 1 located at the neutral position A0 corresponding to about 99 cm and the height position of the operation handle 1 located at the neutral position A0 corresponding to the model of the sitting small operator O2 is about 64 cm. It is preferable to secure a certain value 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 transitioned between the standing position adaptive form and the sitting position adaptive form is caused by the neutral position corresponding to the model of the large operator O1 in the standing position. The height position of the operation handle 1 located at A0 is about 118 cm (the position where the height position of the operation handle 1 located at the neutral position A0 in the upright adaptation mode is the maximum in this model) and the large operator O1 in the sitting position. 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 (1).

  As described above, the adjustment width of the height position of the operation handle 1 when the transition between the standing position adaptive form and the sitting position adaptive form is ensured in order to match the physique of the operator O in the standing position adaptive form. An adjustment range that is preferably set (for example, the height position of the operation handle 1 located at the neutral position A0 corresponding to the model of the large operator O1 and the operation position located at the neutral position A0 corresponding to the model of the small operator O2. It corresponds to the adjustment range (for example, a large operator O1 model) that should be secured in order to match the height difference of the handle 1 with the operator O's physique in the sitting position adaptation mode. 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 is about 6 cm.

  If the position of the operating handle 1 is set higher than the height position of the operating handle 1 located at the neutral position A0 corresponding to the model of the large operator O1 standing up to about 118 cm, this adjustment range is further increased. It will be expanded. Further, it is preferable to secure at least 50 cm from the height position of the position of the operation handle 1 in the standing position adaptive form. Further, the displacement of the height position of the operation handle 1 when the remote control device 100 is transitioned between the standing posture adaptive form and the sitting posture adaptive form is due to the neutral position corresponding to the model of the operator O1 who is standing upright. About 54 cm or more, which is the difference between the height position of the operation handle 1 located at A0 of about 118 cm and the height position of the operation handle 1 located at the neutral position A0 corresponding to the model of the sitting small operator O2 of about 64 cm. It is preferable to secure it. 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.

(Operation target pedal identification process)
With reference to FIG. 15, operation target pedal identification processing by the control unit 61 will be described.

  In step S1 of FIG. 15, the control unit 61 determines whether the sensor 26 detects the foot of the operator O. If the foot of the operator O is detected, the process proceeds to step S2. If the foot of the operator O is not detected, the determination of step S1 is repeated. The control unit 61 determines whether or not the foot of the operator O is detected by the sensor 26f or the sensor 26g in step S2. If the detected sensor 26 is the sensor 26f or the sensor 26g, the process proceeds to step S3. If the detected sensor 26 is not the sensor 26f or the sensor 26g, the process proceeds to step S4.

  In step S3, the control unit 61 specifies the pedal 20 (camera pedal 23, clutch pedal 24) to be operated based on the detection result of the sensor 26 (sensor 26f or sensor 26g). Specifically, when the sensor 26f detects a foot, the control unit 61 identifies the pedal 20 to be operated as the clutch pedal 24. Further, when the foot is detected by the sensor 26g, the control unit 61 specifies that the pedal 20 to be operated is the camera pedal 23.

  The control unit 61 determines whether or not the feet of the operator O are detected by the plurality of sensors 26 in step S4. If the plurality of sensors 26 detect the foot of the operator O, the process proceeds to step S5. If the single sensor 26 detects the foot of the operator O, the process returns to step S1.

  In step S5, the control unit 61 identifies the pedal 20 (cut pedal 22a, coagulation pedal 21a, cut pedal 22b, coagulation pedal 21b) to be operated based on the detection results of the plurality of sensors 26. Specifically, when the plurality of sensors 26a and 26b detect the foot, the control unit 61 identifies the pedal 20 to be operated as the coagulation pedal 21b. Further, when the foot is detected by the plurality of sensors 26 of the sensors 26b and 26c, the control unit 61 identifies the pedal 20 to be operated as the cutting pedal 22b. When the foot is detected by the plurality of sensors 26c and 26d, the control unit 61 identifies the pedal 20 to be operated as the coagulation pedal 21a. When the foot is detected by the plurality of sensors 26d and 26e, the control unit 61 identifies the pedal 20 to be operated as the disconnection pedal 22a.

[Second Embodiment]
Next, a second embodiment of the present invention will be described with reference to FIG. In the second embodiment, an example of a configuration in which the number of sensors 26 is smaller than the number of pedals 20 will be described, unlike the first embodiment in which the number of sensors 26 is larger than the number of pedals 20.

  Here, the operation pedal portion 2c of the second embodiment detects the presence of a plurality of pedals 20 that are operated by being pushed downward and perform a function related to a medical instrument, and a foot that operates the pedals 20. And a plurality of sensors 26 for Further, at least one pedal 20 among the plurality of pedals 20 detects the foot to be operated by using the plurality of sensors 26. That is, when the control unit 61 receives the detection information from the plurality of sensors 26 arranged near one of the plurality of pedals 20 (the first pedal (the coagulation pedal 21 and the cutting pedal 22)). , It is determined that there is a foot that operates a certain pedal 20 (first pedal (coagulation pedal 21 and cutting pedal 22)). With this, for at least one pedal 20, the presence of the foot approaching the pedal 20 to be operated can be detected by the plurality of sensors 26, and thus the pedal 20 approaching the foot of the operator O can be accurately specified. be able to. As a result, it is possible to prevent the accuracy of detecting the presence of the foot operating the pedal 20 to be operated among the plurality of pedals 20 from decreasing.

  Specifically, six pedals 20 are provided. The pedal 20 includes a coagulation pedal 21, a disconnection pedal 22, a camera pedal 23, and a clutch pedal 24. The coagulation pedal 21 includes coagulation pedals 21a and 21b. The cutting pedal 22 also includes cutting pedals 22a and 22b. Further, five sensors 26 are provided. The sensor 26 includes sensors 26a, 26b, 26c, 26d and 26e.

  The presence of a foot approaching the coagulation pedal 21b is detected by the sensors 26a and 26b. That is, when the foot is detected by both the sensors 26a and 26b, the pedal 20 to be operated is identified as the coagulation pedal 21b. Further, the sensor 26c detects the presence of a foot approaching the cutting pedal 22b. That is, when the foot is detected by the sensor 26c, the pedal 20 to be operated is identified as the cutting pedal 22b.

  The sensor 26d detects the presence of a foot approaching the coagulation pedal 21a. That is, when the sensor 26d detects the foot, the pedal 20 to be operated is identified as the coagulation pedal 21a. The sensor 26e detects the presence of a foot approaching the cutting pedal 22a. That is, when the foot is detected by the sensor 26e, the pedal 20 to be operated is identified as the disconnection pedal 22a.

  Further, since the camera pedal 23 and the clutch pedal 24 are sufficiently separated from the other pedals 20, the sensor 26 for detecting the presence of the foot is not provided.

  The other configurations of the second embodiment are similar to those of the first embodiment.

[Third Embodiment]
Next, a third embodiment of the present invention will be described with reference to FIG. In the third embodiment, unlike the first embodiment in which one display unit is attached to the remote control device, an example of a configuration in which a plurality of display units are attached will be described.

  Here, as shown in FIG. 17, a plurality of display units 3 are attached to the remote control device 400 of the third embodiment. In the example shown in FIG. 17, the remote operation device 400 is provided with both the scope-type display unit 3a and the non-scope-type display unit 3b as the display unit 3. The two display units 3 are arranged side by side in the left-right direction (X direction).

  In other words, the remote control device 400 is provided with a plurality (two) of the mounted parts 41. Specifically, the remote control device 400 is provided with a plurality (two) of display unit support arms 4. Then, a mounted portion 41 is provided at the tip of each of the plurality of display portion support arms 4. Accordingly, both the scope-type display unit 3a and the non-scope-type display unit 3b can be attached to the remote control device 400, so that the versatility of the display unit 3 can be effectively increased.

  In the third embodiment, the non-scope type display unit 3b used for one side displays at least one of an image of a surgical portion acquired in advance, information indicating a surgical state, and operation information. For example, the one non-scope type display unit 3b displays an X-ray imaged image captured beforehand and a magnetic resonance image. The 3D image acquired from the endoscope 201b is displayed on the other (the other) scope-type or non-scope-type display unit. As a result, the operator O mainly sees the endoscopic image on the other display unit and at the same time, obtains at least one auxiliary information of the image of the surgical portion, the information indicating the surgical state, and the operation information that are acquired in advance. It is possible to further expand versatility and expandability such as performing an operation while referring to it.

  As described above, the remote control device 400 according to the third 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. A non-scope type display unit 3b is attached as an auxiliary display unit. This makes it possible to select either the immersive type remote control device or the open type remote control device, while also referring to the auxiliary information. Further, since a plurality of attached parts are provided, it is possible to freely select which of the left and right sides the main display part is installed.

  In the example of FIG. 17, the scope-type display unit 3a and the non-scope-type display unit 3b are attached to the two attached portions 41, but the scope-type display unit 3a is attached to both of the attached portions 41. The non-scope type display unit 3b may be attached to both of the two attached parts 41.

  The rest of the configuration of the third embodiment is similar to that of the first embodiment.

[Fourth Embodiment]
Next, a fourth embodiment of the present invention will be described with reference to FIG. In the fourth embodiment, unlike the first and third embodiments in which the display unit is attached to the remote control device, an example of a configuration in which the display device is separately provided will be described.

  Here, in the fourth embodiment, as shown in FIG. 18, a display device 501 is provided separately from the remote control device 500. That is, the display unit is not attached to the remote control device 500. Further, the remote control device 500 is not provided with a display unit support arm that supports the display unit. A remote operation system 502 is configured by the remote operation device 500 and the display device 501 installed outside the remote operation device 500. Thereby, the configuration of the remote control device 500 can be simplified.

  The display device 501 is installed in front of the remote control device 500 (Y2 direction). That is, the display device 501 is arranged at a position where the operator O who operates the remote control device 500 can see the screen. The display device 501 includes a display device such as a liquid crystal display, an organic EL display, and a plasma display, and displays a 2D or 3D image captured by the endoscope 201b. Further, the display device 501 may display at least one of an image of a surgical portion acquired in advance, information indicating a surgical state, and operation information. For example, the display device 501 displays an X-ray captured image captured beforehand and a magnetic resonance image.

  The rest of the configuration of the fourth embodiment is the same as that of the first embodiment.

(Modification)
It should be considered that the embodiments disclosed this time are exemplifications in all points and not restrictive. The scope of the present invention is shown not by the above description of the embodiments but by the scope of the claims, and further includes meanings equivalent to the scope of the claims and all modifications (modifications) within the scope.

  For example, in the above-described first to fourth embodiments, the example of the configuration in which the pedal of the operation pedal unit includes the coagulation pedal and the cutting pedal is shown, but the present invention is not limited to this. In the present invention, the pedal of the operation pedal portion may include a pedal for performing a function related to the medical device other than the coagulation pedal and the cutting pedal.

  Moreover, in the said 1st-4th embodiment, although the sensor was the example of the interruption | blocking type sensor, this invention is not limited to this. In the present invention, the sensor may be transmissive or reflective. Also, the presence of the foot may be detected without using light. For example, a sound wave may be used for detection, or a coil may be used for detection. Further, the sensor is not limited to the non-contact type, and the presence of the foot may be detected by contact. For example, the sensor may be a mechanical switch.

  In the first embodiment, the number of sensors is larger than the number of pedals, and in the second embodiment, the number of sensors is smaller than the number of pedals. Not limited to In the present invention, the number of sensors and the number of pedals may be the same. Further, the number of sensors is not limited to 5 or 6. The number of sensors may be 4 or less, or 7 or more.

  Further, in the above-described first to fourth embodiments, an example of the configuration in which one or two sensors for detecting the presence of the foot is provided for one pedal has been shown, but the present invention is not limited to this. .. In the present invention, one or more pedals may be provided with three or more sensors for detecting the presence of the foot.

  Further, in the first and third embodiments, an example is shown in which the connecting portion 52 of the armrest 5 has a shape that rises forward (on the side where the operator O is located, in the Y1 direction), and in the fourth embodiment described above. Then, the example in which the connecting portion 52 of the armrest 5a has a shape extending in the horizontal direction has been shown, but the present invention is not limited to this. In the present invention, as in the modified example shown in FIG. 19, the connecting portion 52 of the armrest 5b may have a shape that is lowered toward the front. As a result, a large space at the feet of the operator O can be secured.

  Further, in the first to fourth embodiments, one support mechanism 9 for moving the operation handle 1 and the armrest 5 in the vertical direction is provided at substantially the center in the left-right direction (X direction) of the remote operation device. Although an example is shown, the present invention is not limited to this. In the present invention, as in the modification shown in FIG. 19, a pair of support mechanisms 9a may be provided at both ends in the left-right direction (X direction) of the remote control device 600. For example, the support mechanism 9a may include a support portion 91a and a drive portion 92a, and the support portion 91a may be supported by a pair of drive portions 92a arranged on the left and right. The pair of drive units 92a move in the vertical direction by extending and contracting in synchronization with each other.

  Further, in the above-described first to fourth embodiments, the example of the configuration in which the operation pedal portion is provided with six pedals that are operated by being pushed downward, but the present invention is not limited to this. .. In the present invention, the operation pedal portion may be provided with a plurality of pedals other than six pedals.

  In addition, in the first embodiment, an example of a configuration in which one mounted portion 41 to which the display unit 3 is attached is provided is shown. In the third embodiment, the mounted portion 41 to which the display unit 3 is attached is Although an example of the configuration provided with two is shown, the present invention is not limited to this. In the present invention, three or more attached parts 41 to which the display part 3 is attached may be provided.

  Further, in the above-described first to fourth embodiments, an example of a configuration in which the attached display unit 3 is connected to the remote control device via a cable for information communication is shown, but the present invention is not limited to this. I can't. In the present invention, the attached display unit 3 may be connected to the remote operation device by wireless communication so that information communication can be performed.

  Further, in the above-described first to fourth embodiments, the example in which the support mechanism moves the operation handle and the armrest in the vertical direction has been shown, but 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, 2: Operation pedal part, 2a: Base part, 20: Pedal, 21, 21a, 21b: Coagulation pedal (first pedal), 22, 22a, 22b: Disconnection pedal (first pedal), 23 : Camera pedal (second pedal), 24: clutch pedal (second pedal), 26, 26a, 26b, 26c, 26d, 26e, 26f, 26g: sensor, 61: control unit, 100, 400, 500, 600: Remote control device, 200: patient side system (patient side device), 201b: endoscope (imaging unit)

Claims (9)

An operation handle for operating the medical device remotely,
Each pedal is operated by pushing it downwards, and a plurality of pedals for performing a function related to the medical device, and an operation pedal unit including a sensor for detecting the presence of a foot operating the pedals, and
A control unit for receiving detection information from the sensor,
A plurality of the sensors are provided in the vicinity of one first pedal of the plurality of pedals,
The remote control device, wherein the control unit determines that there is a foot operating the first pedal when receiving the detection information from the plurality of sensors arranged in the vicinity of the one first pedal. The plurality of pedals includes a coagulation pedal that coagulates a surgical site and a cutting pedal that performs an operation of cutting the surgical site,
The remote control device according to claim 1, wherein a height of an upper end of the coagulation pedal is different from a height of an upper end of the cutting pedal. The plurality of pedals includes a coagulation pedal that coagulates a surgical site and a cutting pedal that performs an operation of cutting the surgical site,
The remote control device according to claim 1 or 2, wherein a protrusion amount of the coagulation pedal and a protrusion amount of the cutting pedal are different in a plan view. The operation pedal portion has a base portion on which the plurality of pedals are arranged, and a wall portion provided so as to stand up from the base portion,
The remote control device according to claim 1, wherein the base part is movable in a horizontal direction.   The remote control device according to claim 4, wherein the sensor is provided on the base portion and the wall portion.   The remote control device according to claim 1, wherein the number of the sensors is larger than the number of the plurality of pedals.   The remote control device according to claim 1, wherein the number of the sensors is smaller than the number of the pedals. Detects the presence of an operating handle for remotely operating a medical device, a plurality of pedals for performing functions related to the medical device and a plurality of pedals for operating the pedals, which are operated by pushing the respective devices downward. A remote operation device having an operation pedal unit including a sensor for
A patient-side device having the medical device operated by the remote control device;
And a control unit,
A plurality of the sensors are provided in the vicinity of one first pedal of the plurality of pedals,
The operation system, wherein the control unit determines that there is a foot operating the first pedal when receiving the detection information from the plurality of sensors arranged in the vicinity of the one first pedal. A method of specifying a pedal to be operated from among a plurality of pedals that are operated by pressing each foot downwards and perform a function related to a medical device,
Determining whether or not a plurality of sensors arranged near one of the pedals detects the presence of a foot operating the pedal,
Specifying that the pedal arranged in the vicinity of the plurality of sensors is a pedal to be operated when the plurality of sensors detect the presence of a foot operating the pedal. How to identify the target pedal.

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