JP3960746B2 - Surgical microscope equipment - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  In the present invention, the eyepiece is disposed on the microscope body.Surgical microscope equipmentAbout.
[0002]
[Prior art]
In general, for example, in a microscope apparatus used as a surgical microscope, a drape b, which is a sterilization cover, is mounted so as to cover the entire microscope body a as shown in FIG. The drape b is covered so as to cover the entire microscope body a loosely.
[0003]
An eyepiece c is disposed on the microscope body a. The eyepiece c includes a diopter adjustment device (see, for example, Japanese Utility Model Publication No. 60-41532) for adjusting the diopter of the eyepiece, and an eyepiece that is exposed between the eye of the observer and the eyepiece e. Some of them incorporate a movable member such as an eye shade (see, for example, JP-A-9-222569) that prevents intrusion into e.
[0004]
FIG. 7A shows a microscope apparatus in which a diopter adjusting device and an eye shade are incorporated in the eyepiece c. As shown in FIG. 7B, an eyepiece e held by a cylindrical lens holder d is disposed in the eyepiece c of the microscope apparatus. Here, an eyepiece mounting hole f is formed on the microscope body a side. An internal thread portion f1 is formed on the inner peripheral surface of the eyepiece attachment hole f. Furthermore, a male screw portion d1 that is screwed into the female screw portion f1 of the eyepiece lens mounting hole f is formed on the outer peripheral surface of the lens holder d. As the lens holder d is rotated, the male screw part d1 of the lens holder d is screwed along the female screw part f1 of the eyepiece lens mounting hole f as shown in FIG. The diopter is adjusted by moving in the direction.
[0005]
Furthermore, a substantially ring-shaped eye shade attachment hole g is provided on the outer end surface of the lens holder d along the optical axis direction of the eyepiece lens e. A substantially cylindrical eye shade h is inserted into the eye shade mounting hole g so as to be movable along the optical axis direction of the eyepiece lens e. Here, a male screw part g1 is formed on the inner peripheral wall surface of the eye shade mounting hole g. Further, an internal thread portion h1 that is screwed into the external thread portion g1 of the eye shade attachment hole g is formed on the inner peripheral surface of the eye shade h. Then, as shown in FIG. 7C, as the eye shade h is rotated, the female thread portion h1 of the eye shade h is screwed along the male thread portion g1 of the eye shade mounting hole g, so that the eye shade h becomes an eyepiece. The height (projection amount) of the eye shade h is adjusted by being moved in the optical axis direction of e.
[0006]
By the way, in the surgical microscope, as shown in FIG. 7A, only a part of the eyepiece c of the microscope body a, that is, only the part of the eyepiece e where the observer observes the microscope image is exposed to the outside. Is covered with drape b. Here, the drape b is formed with an opening b1 for exposing the portion of the eyepiece lens e to the outside. And the site | part vicinity of the opening part b1 of this drape b is being fixed to the eyepiece part c of the microscope main body a with drape fixing tools i, such as a rubber band.
[0007]
[Problems to be solved by the invention]
In the case of the conventional configuration, when adjusting the diopter of the eyepiece lens e of the eyepiece c, an operation of rotating the lens holder d is required. Similarly, when adjusting the height of the eye shade h, an operation for rotating the eye shade h is required. However, since the lens holder d and the eye shade h are arranged at positions close to the eyes of the user looking into the eyepiece lens e of the eyepiece c, the user actually looks into the eyepiece e of the eyepiece c. However, there is a problem that the operation of rotating the lens holder d and the operation of rotating the eye shade h are difficult to perform.
[0008]
Furthermore, an operator may change during the operation. In such a case, the conventional surgical microscope performs an operation of rotating the lens holder d when adjusting the diopter of the eyepiece lens e of the eyepiece c. Since the portion and the portion that rotates the eye shade h when adjusting the height of the eye shade h are arranged in a non-sterile non-sterile area outside the drape b, the lens of the eyepiece c When the operator directly operates the holder d, the eye shade h, or the like, troublesome operations such as exchanging gloves after the operation are required. Therefore, there is a problem that the operation time becomes long.
[0009]
Further, the operator does not directly operate the lens holder d of the eyepiece c, the eye shade h, or the like, but the assistant other than the operator operates the lens holder d of the eyepiece c, the eye shade h, or the like. When it is performed, it is difficult to accurately instruct the operation, and it takes time to adjust to the state desired by the operator. In addition, depending on the surgeon, there are many cases where the patient is patiently used even if it is not properly adjusted. Therefore, also in this case, there is a problem that the operation time tends to be long.
[0010]
Therefore, in the conventional configuration, for example, it is difficult to perform operations such as diopter adjustment of the eyepiece lens e in the eyepiece portion c and height adjustment of the eye shade h during the operation, so the eyepiece portion c is used. There is a problem that it is difficult to quickly adjust to an appropriate observation state according to the person.
[0011]
  The present invention has been made paying attention to the above circumstances, and its purpose is to easily adjust the diopter at the eyepiece and the operation of the eye shade, etc., and quickly adjust to an appropriate observation state according to the user. be able toSurgical microscope equipmentIs to provide.
[0012]
[Means for Solving the Problems]
  The invention of claim 1Surgical microscopeArranged on the eyepiece of the microscope bodyAn eyepiece tube, a lens holder that holds an eyepiece disposed in the eyepiece, and is supported by the eyepiece tube so as to be movable in the optical axis direction of the eyepiece; and light of the eyepiece A cylindrical rotating member that is supported so as to be rotatable in a direction around the axis of the shaft, an inner end portion is fixed to the rotating member, and an outer end portion is provided to extend in the circumferential direction to the eyepiece tube. An operating lever for diopter adjustment that is extended to the outside of the eyepiece tube through the guide groove, and the operation lever rotates in the circumferential direction of the eyepiece tube along the guide groove. A conversion mechanism that converts a rotation operation of the rotation member that rotates together with an operation lever in a direction around the optical axis of the eyepiece lens into an axial movement operation of the lens holder; and the lens holder along the lens holder An eye shade supported so as to protrude and retract with respect to the eyepiece, and the eyepiece A slide member that is supported so as to be movable along the axial direction of the optical axis of the lens and whose front end is fixed to the eye shade, and a position in the eyepiece tube that is separated from the eye shade in the optical axis direction of the eyepiece An operation unit for adjusting the height of the eyeshade disposed on the drive unit, a drive mechanism for sliding the slide member along the axial direction of the optical axis of the eyepiece by operation of the operation unit, and a microscope main body. A sterilization cover that is mounted and covers the entire microscope body, an opening formed in the sterilization cover and opening a portion corresponding to the eyepiece tube in the eyepiece, and the opening of the sterilization cover A drape fixing tool for fixing a vicinity portion to the eyepiece tube, and the diopter adjusting operation lever and the eye shade height adjusting operation portion are connected to the lens holder. In the position distant from the preliminary the eyeshade in the optical axis direction of the eyepiece, and the sterile cover is disposed inside the portion that is mountedIt is characterized bySurgical microscope equipmentIt is.
  In the invention of claim 1,An operation lever for adjusting the diopter of the eyepiece is arranged at a position away from the lens holder in the optical axis direction of the eyepiece, and is rotated by a conversion mechanism according to the rotation of the rotation member when the operation lever is rotated. By converting the rotation operation of the member into the parallel movement operation of the lens holder that translates along the optical axis direction of the eyepiece lens, the eyepiece lens moves in the optical axis direction and the diopter adjustment of the eyepiece lens is performed. Therefore, when adjusting the diopter of the eyepiece of the eyepiece, the user can perform an operation of rotating the operation lever at a position away from the position of the eye actually looking into the eyepiece of the eyepiece. Compared to the above, it is easier to adjust the diopter of the eyepiece in the eyepiece, and it is possible to quickly adjust to an appropriate observation state according to the user.
  The diopter adjustment lever is located inside the part where the sterilization cover is attached. When adjusting the diopter of the eyepiece during surgery, it must be in contact with the operation lever via the sterilization cover. Since the operation lever is turned, the operator in the sterilization area can directly operate the operation lever in the non-sterilization area from above the sterilization cover. This eliminates the need for troublesome operations such as changing gloves after the operator operates the control lever when adjusting the diopter of the eyepiece, so it is easy to adjust the diopter of the eyepiece, depending on the user. It is possible to quickly adjust to an appropriate observation state, which has a great effect on shortening the operation time.
  Furthermore, since the lens holder is translated along the optical axis direction of the eyepiece when the diopter adjusting operation lever is operated, it is possible to prevent the eyepiece from rotating during diopter adjustment. Thereby, for example, even when an irregular lens such as a substantially rectangular eyepiece is provided, the diopter adjustment can be performed without rotating the irregular lens during diopter adjustment.
  In addition, an eyeshade drive mechanism is provided by a drive mechanism that slides the eyeshade in parallel along the optical axis direction of the eyepiece, so that the eyeshade rotates around the axis of the eyepiece when adjusting the height of the eyeshade. Can be prevented. For this reason, it is possible to prevent the positions of the left and right eye shades from rotating around the axis of the eyepiece when adjusting the height of the eye shade.
  The operation part for adjusting the height of the eye shade is arranged inside the part where the sterilization cover is attached. When adjusting the height of the eye shade during the operation, it is connected to the operation part via the sterilization cover. Since the operation part is rotated in the contact state, the surgeon in the sterilization area can directly operate the operation part in the non-sterilization area from above the sterilization cover. This eliminates the need for troublesome operations such as changing gloves after the operator has operated the operating unit when adjusting the height of the eye shade, making it easy to adjust the height of the eye shade. It is possible to quickly adjust to an appropriate observation state, which has a great effect on shortening the operation time. As a result, it is easy to adjust the diopter at the eyepiece part of the surgical microscope equipped with a sterilization cover that covers the entire microscope body, and to perform operations such as eyeshades, and quickly achieve an appropriate observation state according to the user. adjustIt is what I did.
[0020]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, a first embodiment of the present invention will be described with reference to FIGS. FIG. 1 shows a schematic configuration of the entire surgical microscope 1. The gantry 2 of the surgical microscope 1 is provided with a base 3 that can move on the floor surface and a column 4 that is erected on the base 3.
[0021]
Furthermore, an arm portion 6 that supports a mirror body (microscope main body) 5 of the surgical microscope 1 so as to be movable in an arbitrary direction is provided on the upper portion of the support column 4. The arm portion 6 is provided with a plurality of movable arms. Here, the movable arms are connected to each other so as to be rotatable about a rotation axis.
[0022]
In addition, an electromagnetic brake (not shown) is provided in each bearing portion of each rotating shaft of the arm portion 6. This electromagnetic brake is turned on and off by a switch (not shown) provided on a grip fixed integrally to the mirror body 5, for example. When the electromagnetic brake is turned off, the arm unit 6 is held in the unlocked state. Thereby, the mirror 5 can be moved three-dimensionally, and the operator can observe the surgical site from a desired angle by adjusting the position freely in space. Further, when the electromagnetic brake is turned on, the arm portion 6 is switched to the locked state, and the position of the mirror body 5 is fixed. The surgical microscope 1 has a built-in microscope light source 32 for illuminating the patient's surgical site.
[0023]
Further, the eyepiece portion 7 is provided on the mirror body 5 of the surgical microscope 1 as shown in FIG. The eyepiece 7 is provided with a pair of left and right eyepieces 8 (both eyes). Since the left and right eyepiece cylinders 8 have substantially the same configuration, the configuration of one eyepiece cylinder 8 will be described here, and the other will be given the same reference numeral and the description thereof will be omitted.
[0024]
The eyepiece tube 8 is formed with an eyepiece mounting hole 10 into which the eyepiece unit 9 is inserted. A small-diameter portion 10a and a large-diameter female screw portion 10b disposed on the entrance side of the small-diameter portion 10a are formed on the inner peripheral surface of the eyepiece mounting hole 10.
[0025]
The eyepiece unit 9 is provided with a substantially cylindrical lens holder (movable member) 11. Inside the lens holder 11, an eyepiece 12 in which a plurality of lenses are combined is disposed on the tip side.
[0026]
Further, a large-diameter flange portion 13 is projected from the outer peripheral surface of the lens holder 11 at a substantially central position in the optical axis direction of the eyepiece lens 12. On the outer peripheral surface of the flange portion 13, a male screw portion 13 a that is screwed with the female screw portion 10 b of the eyepiece lens mounting hole 10 is formed. A diopter adjusting screw (moving means) 14 of the eyepiece 12 is formed by a threaded portion between the male threaded portion 13a of the lens holder 11 and the female threaded portion 10b of the eyepiece mounting hole 10. As a result, as the lens holder 11 is rotated, the male screw portion 13a of the lens holder 11 is screwed along the female screw portion 10b of the eyepiece lens mounting hole 10 to move the eyepiece lens 12 in the optical axis direction. Yes. Accordingly, the diopter adjustment is performed by converting the rotation operation of the lens holder 11 into the axial movement operation of the lens holder 11 by the threaded portion of the male screw portion 13a of the lens holder 11 and the female screw portion 10b of the eyepiece lens mounting hole 10. A position adjusting mechanism (conversion mechanism) for performing the above is formed.
[0027]
Further, the base end side of the lens holder 11 passes through the small diameter portion 10 a of the eyepiece lens mounting hole 10, and further extends to the inner side (back side) of the eyepiece lens mounting hole 10. A first spur gear 15 for transmitting driving force is formed on the outer peripheral surface of the lens holder 11 on the base end side.
[0028]
The eyepiece tube 8 is provided with a diopter adjustment operation knob (operation unit) 16 for operating the diopter adjustment screw 14 of the eyepiece 12. The operation knob 16 is disposed at a position away from the lens holder 11 in the optical axis direction of the eyepiece lens 12.
[0029]
Further, a gear mechanism (operation force transmission means) 17 for transmitting the operation force of the operation knob 16 to the diopter adjustment screw 14 of the eyepiece 12 is provided between the operation knob 16 and the lens holder 11. Here, the rotating shaft 16a of the operation knob 16 is inserted into the eyepiece tube 8 and is rotatably supported. The operation knob 16 is fixed to one end (outer end) of the rotating shaft 16a.
[0030]
The gear mechanism 17 is provided with a first bevel gear 18 fixed to the other end (inner end) of the rotary shaft 16a. A second bevel gear 19 is meshed with the first bevel gear 18. The second bevel gear 19 is fixed to one end portion of a rotating shaft 21 that is rotatably supported by a bearing portion 20 projecting from the inner wall surface of the eyepiece tube 8. The rotation shaft 21 is disposed in parallel with the optical axis direction of the eyepiece 12.
[0031]
A second spur gear 22 that meshes with the first spur gear 15 of the lens holder 11 is fixed to the other end of the rotating shaft 21. The second spur gear 22 is set to have a smaller tooth width than the first spur gear 15. When the operation knob 16 is rotated, the first bevel gear 18 is driven to rotate simultaneously through the rotation shaft 16a. Further, in conjunction with the rotation of the first bevel gear 18, the rotation shaft 21 is driven to rotate via the meshing portion between the first bevel gear 18 and the second bevel gear 19, and the rotation of the rotation shaft 21 is reduced. It is transmitted to the lens holder 11 side through the meshing part of the second spur gear 22 and the first spur gear 15 so that the lens holder 11 is rotationally driven around the axis. At this time, as the lens holder 11 rotates, the male screw portion 13a of the lens holder 11 is screwed along the female screw portion 10b of the eyepiece lens mounting hole 10 to move the eyepiece lens 12 in the optical axis direction to adjust the diopter. Is supposed to do. The rotation shaft 16 a of the operation knob 16, the first bevel gear 18, the second bevel gear 19, the rotation shaft 21, the second spur gear 22, and the first spur gear 15 are used. A diopter adjusting gear mechanism 17 for transmitting the operating force of the operating knob 16 to the diopter adjusting screw 14 of the eyepiece 12 is formed.
[0032]
Further, an eye shade 23 for preventing external light from entering the inside of the eyepiece 12 from between the eye of the observer and the eyepiece 12 is disposed at the tip of the lens holder 11. Here, a male thread portion 24 for attaching an eye shade is formed on the outer peripheral surface of the tip portion of the lens holder 11.
[0033]
Further, the eye shade 23 is provided with a flange-like eyepiece 26 projecting from the tip of a substantially cylindrical eye shade main body 25. Furthermore, an internal thread portion 27 that is screwed with the external thread portion 24 of the lens holder 11 is formed on the inner peripheral surface of the eye shade body 25. A screw 28 for adjusting the height (projection amount) of the eye shade 23 is formed by a threaded portion between the female screw portion 27 of the eye shade 23 and the male screw portion 24 of the lens holder 11. As a result, the internal thread portion 27 of the eye shade 23 is screwed along the external thread portion 24 of the lens holder 11 in accordance with the rotation operation of the eye shade 23 so as to move the eye shade 23 in the optical axis direction of the eyepiece lens 12. It has become.
[0034]
As shown in FIG. 1, the surgical microscope 1 of the present embodiment is equipped with a drape 29 that is a sterilization cover that covers the entire main body of the microscope 1. As shown in FIG. 3, the drape 29 is formed with an opening 30 having openings corresponding to the left and right eyepiece cylinders 8 in the eyepiece 7 of the body 5 of the surgical microscope 1. And the site | part vicinity of the opening part 30 of this drape 29 is being fixed to the eyepiece cylinder 8 of the eyepiece part 7 with drape fixing tools 31, such as a rubber band. Here, the diopter adjusting operation knob 16 is disposed inside the mounting portion of the drape 29. When the diopter of the eyepiece 12 is adjusted during the operation, the operation knob 16 is rotated while being in contact with the operation knob 16 via the drape 29.
[0035]
Next, the operation of the above configuration will be described. When the diopter adjustment of the eyepiece 12 of the eyepiece 7 is performed when using the surgical microscope 1 of the present embodiment, the diopter adjustment operation knob 16 of the eyepiece tube 8 is rotated. At this time, since the entire main body of the microscope 1 is covered with the drape 29 which is a sterilization cover, the operation knob 16 is rotated while being in contact with the operation knob 16 via the drape 29.
[0036]
When the operation knob 16 is rotated, the first bevel gear 18 is simultaneously driven to rotate through the rotation shaft 16a. Further, in conjunction with the rotation of the first bevel gear 18, the rotation shaft 21 is driven to rotate via the meshing portion between the first bevel gear 18 and the second bevel gear 19, and the rotation of the rotation shaft 21 is reduced. It is transmitted to the lens holder 11 side through the meshing part of the second spur gear 22 and the first spur gear 15, and the lens holder 11 is driven to rotate about the axis. At this time, with the rotation of the lens holder 11, the male screw portion 13 a of the lens holder 11 is screwed along the female screw portion 10 b of the eyepiece lens mounting hole 10, so that the entire eyepiece lens unit 9 is moved in the optical axis direction of the eyepiece lens 12. Moving. Thereby, the eyepiece 12 moves in the optical axis direction, and the diopter adjustment of the eyepiece 12 is performed.
[0037]
Further, when adjusting the height of the eye shade 23, the eye shade 23 is rotated. At this time, as the eye shade 23 is rotated, the female thread portion 27 of the eye shade 23 is screwed along the male thread portion 24 of the lens holder 11 so that the entire eye shade 23 moves in the optical axis direction of the eyepiece lens 12. . Thereby, the height adjustment of the eye shade 23 is performed.
[0038]
Therefore, the above configuration has the following effects. That is, in the present embodiment, the operation knob 16 for adjusting the diopter of the eyepiece 12 is disposed at a position away from the lens holder 11 of the eyepiece unit 9 in the optical axis direction of the eyepiece 12, and the operation knob 16 and the eyepiece are arranged. Since the gear mechanism 17 for transmitting the operation force of the operation knob 16 to the diopter adjustment screw 14 is provided between the lens holder 11 of the unit 9 and the diopter of the eyepiece 12 of the eyepiece 7 is adjusted by the user. The operation knob 16 can be rotated at a position away from the position of the eye actually looking through the eyepiece 12 of the eyepiece 7. Therefore, the diopter adjustment operation of the eyepiece lens 12 of the eyepiece unit 7 is easier to perform than in the prior art, and it is possible to quickly adjust to an appropriate observation state according to the user.
[0039]
Further, in the present embodiment, the operation knob 16 for adjusting the diopter is arranged inside the mounting portion of the drape 29, and when adjusting the diopter of the eyepiece 12 during the operation, the operation knob 16 is provided via the drape 29. Since the operation knob 16 is rotated while being in contact with the sterilization area, the operator in the sterilization area can directly rotate the operation knob 16 in the non-sterile area from the top of the drape 29. This eliminates the need for troublesome operations such as changing the glove after the operator rotates the operation knob 16 when adjusting the diopter of the eyepiece 12, making it easy to adjust the diopter of the eyepiece 12. It is possible to quickly adjust to an appropriate observation state according to the person, and there is a great effect in shortening the operation time.
[0040]
4 and 5 show a second embodiment of the present invention. In the present embodiment, the configuration of the eyepiece 7 of the surgical microscope 1 according to the first embodiment (see FIGS. 1 to 3) is changed as follows. The other parts have the same configuration as the surgical microscope 1 of the first embodiment, and the same parts as those of the surgical microscope 1 of the first embodiment are denoted by the same reference numerals. Then, the explanation is omitted.
[0041]
That is, in this embodiment, instead of the diopter adjusting operation knob 16 of the first embodiment, an operation lever that rotates about 180 ° along the circumferential direction of the eyepiece tube 8 as shown in FIG. 41 is provided. As shown in FIG. 5, the operation lever 41 protrudes from the outer peripheral surface of a ring-shaped rotating member 42 that is rotatably held in the tube of the eyepiece tube 8. On the inner peripheral surface of the rotating member 42, a female screw portion 43 of a helicoid screw is formed in which the amount of movement of the eyepiece lens 12 in the optical axis direction is larger than the amount of rotation of the eyepiece lens 12 in the direction around the axis.
[0042]
A male screw portion 44 that is screwed with the female screw portion 43 of the rotating member 42 is formed on the outer peripheral surface of the lens holder 11 of the eyepiece lens unit 9 on the proximal end side. A diopter adjusting screw (moving means) 45 of the eyepiece 12 is formed by a screwed portion of a helicoid screw between the male screw portion 44 of the lens holder 11 and the female screw portion 43 of the rotating member 42. .
[0043]
Further, a guide groove 46 that guides the turning operation of the operation lever 41 of the turning member 42 and a long groove 47 that restricts the turning operation of the lens holder 11 are provided on the outer peripheral surface of the eyepiece tube 8. Here, the guide groove 46 is extended by about 180 ° along the circumferential direction of the eyepiece tube 8. The long groove 47 extends along the axial direction of the eyepiece tube 8.
[0044]
Further, a rotation restricting pin 48 projects from the outer peripheral surface on the tip end side of the lens holder 11. The rotation restricting pin 48 is inserted into the long groove 47 of the eyepiece tube 8. When the operation lever 41 is rotated, the rotation member 42 is rotated together with the operation lever 41. At this time, the rotation operation of the lens holder 11 is restricted by the engaging portion between the rotation restricting pin 48 and the long groove 47 of the eyepiece tube 8. Therefore, during the turning operation of the turning member 42, the turning operation of the turning member 42 is performed via the screwed portion of the helicoid screw between the male screw portion 44 of the lens holder 11 and the female screw portion 43 of the turning member 42. The eyepiece 12 is moved in the direction of the optical axis by being converted into a parallel movement operation of the lens holder 11 that moves in parallel along the direction of the optical axis of the eyepiece 12.
[0045]
Further, in the eyepiece unit 9 of the present embodiment, a substantially planar cutout portion 49 is formed by notching the upper and lower portions of the circular eyepiece lens 12 as shown in FIG. A substantially rectangular irregular-shaped lens 50 is provided. The deformed lenses 50 of the two (both eyes) eyepiece cylinders 8 arranged on the left and right are arranged in the same direction, and are set in a state in accordance with the position of the human eye.
[0046]
Further, the eye shade 23 according to the present embodiment is formed with an extending portion 51 that extends outward from the portion of the eyepiece portion 26. When the observer focuses on the eyepiece 7, the extension portions 51 of the left and right eye shades 23 prevent external light from entering from both sides of the observer's face. Yes.
[0047]
Next, the operation of the present embodiment having the above configuration will be described. In the present embodiment, when adjusting the diopter of the eyepiece 12 of the eyepiece 7 when the surgical microscope 1 is used, the operation lever 41 for adjusting the diopter of the eyepiece tube 8 is set in the circumferential direction of the eyepiece tube 8. Rotate along At this time, since the entire main body of the microscope 1 is covered with the drape 29 which is a sterilization cover, the operation lever 41 is rotated while being in contact with the operation lever 41 via the drape 29.
[0048]
When the operation lever 41 is rotated, the rotation member 42 rotates together with the operation lever 41. At this time, since the rotation operation of the lens holder 11 is restricted by the engagement portion between the rotation restriction pin 48 and the long groove 47 of the eyepiece tube 8, the male screw portion 44 of the lens holder 11 is turned when the turning member 42 is turned. And the parallel movement of the lens holder 11 in which the rotational movement of the rotational member 42 translates along the optical axis direction of the eyepiece lens 12 through the screwed portion of the helicoid screw between the female threaded portion 43 of the rotational member 42. Converted to moving motion. Thereby, the eyepiece 12 moves in the optical axis direction, and the diopter adjustment of the eyepiece 12 is performed.
[0049]
Therefore, the above configuration has the following effects. That is, in the present embodiment, the operation lever 41 for adjusting the diopter of the eyepiece 12 is disposed at a position away from the lens holder 11 of the eyepiece unit 9 in the optical axis direction of the eyepiece 12, and the operation lever 41 is rotated. During the moving operation, the diopter adjusting screw 45 which is a screwed portion of the helicoid screw between the male screw portion 44 of the lens holder 11 and the female screw portion 43 of the rotating member 42 is associated with the rotating operation of the rotating member 42. Thus, by converting the rotation operation of the rotation member 42 into the parallel movement operation of the lens holder 11 that translates along the optical axis direction of the eyepiece lens 12, the eyepiece lens 12 moves in the optical axis direction to move the eyepiece lens 12. The diopter adjustment is performed. Therefore, also in the present embodiment, when adjusting the diopter of the eyepiece 12 of the eyepiece 7, the operation lever 41 is rotated at a position away from the eye where the user is actually looking into the eyepiece 12 of the eyepiece 7. Since the operation can be performed, the diopter adjustment operation of the eyepiece lens 12 of the eyepiece unit 7 is easier to perform than in the prior art, and can be quickly adjusted to an appropriate observation state according to the user.
[0050]
Further, in the present embodiment, the operation lever 41 for adjusting the diopter is arranged inside the mounting portion of the drape 29. When adjusting the diopter of the eyepiece 12 during the operation, the operation lever 41 is operated via the drape 29. Since the operation lever 41 is rotated while being in contact with the sterilization area, an operator in the sterilization area can directly operate the operation lever 41 in the non-sterilization area from the top of the drape 29. This eliminates the need for troublesome operations such as changing gloves after the operator operates the operation lever 41 when adjusting the diopter of the eyepiece 12, so that the user can easily adjust the diopter of the eyepiece 12. Therefore, it is possible to quickly adjust to an appropriate observation state according to the condition, which has a great effect on shortening the operation time.
[0051]
Furthermore, in the present embodiment, the lens holder 11 of the eyepiece unit 9 is translated along the optical axis direction of the eyepiece 12 when the operation lever 41 for diopter adjustment is operated. It is possible to prevent the lens 12 from rotating. For example, when observing a substantially rectangular image picked up by the image sensor through the eyepiece 12, the rectangular shape of the cross section of the eyepiece 12 may be more suitable than the circle. That is, as shown in FIG. 4, a substantially rectangular irregular lens 50 is provided. In this case, since the eye shade 23 can also be translated along the optical axis direction of the eyepiece 12 integrally with the lens holder 11 after the height adjustment, each extending portion 51 can be adjusted even if the diopter is adjusted. Can always be located on the left and right sides of the eye.
[0052]
Further, in the present embodiment, when adjusting the diopter of the eyepiece lens 12, the operation lever 41 is rotated by about 180 ° along the circumferential direction of the eyepiece tube 8, so the operation knob 16 for adjusting the diopter is used. The operation can be further simplified and can be easily used as compared with the case of rotating the.
[0053]
FIG. 6 shows a third embodiment of the present invention. In this embodiment, the configuration of the eyepiece 7 of the surgical microscope 1 according to the second embodiment (see FIGS. 4 and 5) is changed as follows. The other parts have the same configuration as the surgical microscope 1 of the first embodiment and the second embodiment, and the surgical microscopes of the first embodiment and the second embodiment. The same parts as those in FIG.
[0054]
That is, in the present embodiment, the eye shade driving mechanism 61 that slides the eye shade 23 in parallel along the optical axis direction of the eyepiece lens 12 is provided in the configuration of the eyepiece unit 7 of the second embodiment. is there.
[0055]
The eye shade drive mechanism 61 is provided with an operation knob (operation unit) 62 for adjusting the height of the eye shade 23. The operation knob 62 is disposed at a position away from the eye shade 23 in the eyepiece tube 8 in the optical axis direction of the eyepiece 12. Further, the operation knob 62 is disposed inside the mounting portion of the drape 29. When adjusting the height of the eye shade 23 during the operation, the operation knob 62 is in contact with the operation knob 62 via the drape 29. It is designed to rotate.
[0056]
In addition, a link mechanism (operation force transmission means) 63 that slides the eye shade 23 along the optical axis direction of the eyepiece 12 by operation of the operation knob 62 is provided between the operation knob 62 and the eye shade 23. ing. The link mechanism 63 is provided with a rod-shaped guide member 64 supported on the eyepiece tube 8 so as to be movable in the optical axis direction of the eyepiece lens 12. The eye shade 23 is fixed to one end of the guide member 64. The eye shade 23 according to the present embodiment is supported by the eyepiece tube 8 so as to be movable in the optical axis direction of the eyepiece 12.
[0057]
The rotating shaft 62a of the operation knob 62 is inserted into the eyepiece tube 8 and is rotatably supported. The operation knob 62 is fixed to one end (outer end) of the rotating shaft 62a. Further, a feed screw 65 is formed on the rotation shaft 62 a of the operation knob 62.
[0058]
Further, a nut member 66 is screwed to the feed screw 65. When the feed screw 65 rotates, the nut member 66 is moved in the axial direction of the feed screw 65.
[0059]
Further, one end of a link arm 67 of the link mechanism 63 is rotatably connected to the nut member 66. The other end of the link arm 67 is rotatably connected to the middle part of the guide member 64. When the operation knob 62 is rotated, the feed screw 65 is rotationally driven together with the operation knob 62. Further, as the feed screw 65 rotates, the nut member 66 is moved in the axial direction of the feed screw 65. The guide member 64 is moved in the optical axis direction of the eyepiece lens 12 via the link arm 67 in conjunction with the movement of the nut member 66, and the eyeshade 23 is moved in the optical axis direction of the eyepiece lens 12 by the guide member 64. The height of the eye shade 23 is adjusted by being moved.
[0060]
Next, the operation of the above configuration will be described. In the present embodiment, when adjusting the diopter of the eyepiece 12 of the eyepiece 7 when the surgical microscope 1 is used, the operation lever 41 for adjusting the diopter of the eyepiece tube 8 is set in the circumferential direction of the eyepiece tube 8. Rotate along At this time, since the entire main body of the microscope 1 is covered with the drape 29 which is a sterilization cover, the operation lever 41 is rotated while being in contact with the operation lever 41 via the drape 29. Thereby, the eyepiece 12 moves in the optical axis direction as in the second embodiment, and the diopter adjustment of the eyepiece 12 is performed.
[0061]
Further, when adjusting the height of the eye shade 23, the operation knob 62 for adjusting the height of the eye shade 23 is rotated. When the operation knob 62 is rotated, the feed screw 65 is rotationally driven together with the operation knob 62, and the nut member 66 is moved in the axial direction of the feed screw 65 as the feed screw 65 rotates. The guide member 64 is moved in the optical axis direction of the eyepiece lens 12 via the link arm 67 in conjunction with the movement of the nut member 66, and the eyeshade 23 is moved in the optical axis direction of the eyepiece lens 12 by the guide member 64. The height of the eye shade 23 is adjusted by being moved.
[0062]
Therefore, the above configuration has the following effects. That is, in the present embodiment, the operation lever 41 for adjusting the diopter of the eyepiece 12 is disposed at a position away from the lens holder 11 of the eyepiece unit 9 in the optical axis direction of the eyepiece 12, and the operation lever 41 is rotated. As in the second embodiment, the eyepiece 12 is moved in the optical axis direction and the diopter adjustment of the eyepiece 12 is performed in the same manner as in the second embodiment. When the diopter of the lens 12 is adjusted, the operation lever 41 can be rotated at a position away from the eye position where the user is actually looking through the eyepiece lens 12 of the eyepiece unit 7. It is easy to adjust the diopter of the eyepiece 12 of the eyepiece 7, and it is possible to quickly adjust to an appropriate observation state according to the user.
[0063]
Also in the present embodiment, the operation lever 41 for adjusting the diopter is disposed inside the mounting portion of the drape 29. When adjusting the diopter of the eyepiece 12 during the operation, the operation lever 41 is operated via the drape 29. Since the operation lever 41 is rotated while being in contact with the sterilization area, an operator in the sterilization area can directly operate the operation lever 41 in the non-sterilization area from the top of the drape 29. This eliminates the need for troublesome operations such as changing gloves after the operator operates the operation lever 41 when adjusting the diopter of the eyepiece 12, so that the user can easily adjust the diopter of the eyepiece 12. Therefore, it is possible to quickly adjust to an appropriate observation state according to the condition, which has a great effect on shortening the operation time.
[0064]
Furthermore, in the present embodiment, the lens holder 11 of the eyepiece unit 9 is translated along the optical axis direction of the eyepiece 12 when the operation lever 41 for diopter adjustment is operated. It is possible to prevent the lens 12 from rotating. For example, when observing a substantially rectangular image picked up by the image sensor through the eyepiece 12, the rectangular shape of the cross section of the eyepiece 12 may be more suitable than the circle. That is, as shown in FIG. 4, a substantially rectangular irregular lens 50 is provided. In this case, since the eye shade 23 can also be translated along the optical axis direction of the eyepiece 12 integrally with the lens holder 11 after the height adjustment, each extending portion 51 can be adjusted even if the diopter is adjusted. Can always be located on the left and right sides of the eye.
[0065]
Further, in the present embodiment, when adjusting the diopter of the eyepiece lens 12, the operation lever 41 is rotated by about 180 ° along the circumferential direction of the eyepiece tube 8, so the operation knob 16 for adjusting the diopter is used. The operation can be further simplified and can be easily used as compared with the case of rotating the.
[0066]
Further, in the present embodiment, since the eye shade driving mechanism 61 that slides the eye shade 23 in parallel along the optical axis direction of the eyepiece lens 12 is provided, the eye shade 23 is in contact with the eye shade 23 when the height of the eye shade 23 is adjusted. It is possible to prevent the lens 12 from rotating around the axis. Therefore, it is possible to prevent the positions of the extending portions 51 of the left and right eye shades 23 from rotating in the direction around the axis of the eyepiece 12 when the height of the eye shade 23 is adjusted.
[0067]
Further, in the present embodiment, the operation knob 62 for adjusting the height of the eye shade 23 is arranged inside the mounting portion of the drape 29, and when adjusting the height of the eye shade 23 during the operation, the drape 29 is interposed. Since the operation knob 62 is rotated while being in contact with the operation knob 62, the surgeon in the sterilized area can directly operate the operation knob 62 in the non-sterile area from above the drape 29. . This eliminates the need for troublesome operations such as exchanging gloves after the operator operates the operation knob 62 when adjusting the height of the eye shade 23. Therefore, it is possible to quickly adjust to an appropriate observation state according to the condition, which has a great effect on shortening the operation time.
[0068]
Furthermore, the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the scope of the present invention.
Next, other characteristic technical matters of the present application are appended as follows.
Record
(Additional Item 1) An eyepiece for use in a surgical microscope, which is a displacement member, a driving means for moving the displacement member, and a power for transmitting the power from the driving means to the displacement member. A surgical microscope having a transmission means and a fixing portion for fixing the drape, wherein the driving means is provided at a position located inside the drape when the drape is attached to the surgical microscope. Eyepiece for use.
[0069]
(Additional Item 2) In an eyepiece for use in a surgical microscope having a diopter adjustment mechanism, a displacement member that is displaced in order to change the diopter, a drive unit that moves the displacement member, and the drive An eyepiece comprising: transmission means for transmitting power from the means to the displacement member.
[0070]
(Additional Item 3) An additional item having a fixing part for fixing the drape and providing the driving means at a position located inside the drape when the drape is mounted on a surgical microscope. The eyepiece described in 2.
[0071]
(Additional Item 4) The eyepiece according to Additional Item 2, wherein the driving unit is a unit that displaces the displacement member by a linear motion not involving rotation.
[0072]
(Additional Item 5) In an eyepiece for use in a surgical microscope having an eyeshade height adjustment mechanism, a displacement member that is displaced to change the diopter, and a driving unit that moves the displacement member; An eyepiece comprising: transmission means for transmitting power from the driving means to the displacement member.
[0073]
(Additional Item 6) An additional item having a fixing portion for fixing the drape and providing the driving means at a position located inside the drape when the drape is attached to a surgical microscope. 5. The eyepiece lens according to 5.
[0074]
(Additional Item 7) The eyepiece according to Additional Item 5, wherein the driving unit is a unit that displaces the displacement member by a linear motion without rotation.
[0075]
(Additional Item 8) An eyepiece for use in a surgical microscope equipped with a moving means for moving the displacement member and an operation member for operating the moving means, and a fixing portion for fixing the drape An eyepiece for a surgical microscope comprising: the operating member provided at a position located inside the drape when the drape is attached to the surgical microscope.
[0076]
(Additional Item 9) The eyepiece for a surgical microscope according to Additional Item 8, wherein the displacement member is means for changing diopter.
[0077]
(Additional Item 10) The eyepiece for a surgical microscope according to Additional Item 8, wherein the displacement member is a means for changing a height of an eye shade.
[0078]
(Additional Item 11) The eyepiece according to Additional Item 8, wherein the moving unit is a unit that displaces the displacement member by a linear motion not involving rotation.
[0079]
(Conventional technologies 1 to 9 and 11) The eyepiece lens holding the eyepiece is composed of a helicoid or the like, and is rotated up and down to operate the tip of the eyepiece lens that goes out of the drape. Was.
[0080]
(Problems to be solved by Supplementary Items 1 to 9 and 11) In this case, the operation cannot be performed after the drape is put on, and when the operator changes, the glove has to be replaced after the adjustment operation.
[0081]
(Objectives of Additional Items 1 to 9 and 11) During the operation, the objective was to enable the diopter adjustment of the eyepiece lens to be operated while maintaining a sterilized state.
[0082]
(Effects of Supplementary Items 1 to 9 and 11) An operator in a sterilized region can operate from above the drape. Moreover, it is a lever type and easy.
[0083]
(Prior Art of Additional Item 10) An eye shade for preventing external light (unnecessary) from entering the eyepiece is provided on the upper part of the eyepiece, and can be adjusted by rotating or vertically moving the eyepiece. It was a mechanism.
[0084]
(Problem to be solved by Supplementary Item 10) Similar to the diopter correction, since it was a non-sterile area that comes out of the drape, it could not be operated by an operator in the sterile area.
[0085]
(Purpose of Supplementary Item 10) It is intended that an operator in a sterilized state can perform eye shade adjustment during the operation.
[0086]
(Effect of Supplementary Item 10) Easy operation from above the drape. The surgeon in the sterilized area can do it as it is.
[0087]
【The invention's effect】
  According to the invention of claim 1,ContactDiopter adjustment in the eye part and operations such as eye shade are easy to perform, and it is possible to quickly adjust to an appropriate observation state according to the user.
[Brief description of the drawings]
FIG. 1 is a side view showing a schematic configuration of an entire operation microscope according to a first embodiment of the present invention.
FIG. 2 is a front view showing an eyepiece part in the surgical microscope according to the first embodiment.
3 is a cross-sectional view taken along line III-III in FIG.
FIG. 4 is a front view showing an eyepiece part in a surgical microscope according to a second embodiment of the present invention.
5 is a cross-sectional view taken along line VV in FIG.
FIG. 6 is a longitudinal sectional view of an eyepiece part in a surgical microscope according to a third embodiment of the present invention.
FIG. 7A is a side view of an eyepiece in a conventional surgical microscope, and FIG. 7B is a state in which the eyepiece is moved to the shortest position in the eyepiece length adjustment range of the eyepiece or eyeshade. The longitudinal cross-sectional view of the eyepiece which shows, (C) is the longitudinal cross-sectional view of the eyepiece which shows the state moved to the eyepiece of the eyepiece and the longest position of the eye shade length adjustment range.
[Explanation of symbols]
1 Surgical microscope
5 Mirror body (microscope body)
7 Eyepiece
11 Lens holder (movable member)
12 Eyepiece
14 Diopter adjustment screw (moving means)
16 Operation knob (operation unit)
17 Gear mechanism (operating force transmission means)
23 Eye shade (movable member)

Claims (1)

An eyepiece tube disposed on the eyepiece of the microscope body of the surgical microscope ;
A lens holder that holds an eyepiece disposed in the eyepiece and is supported so as to be movable in the optical axis direction of the eyepiece with respect to the eyepiece tube;
A cylindrical rotating member supported so as to be rotatable around the optical axis of the eyepiece;
For diopter adjustment, the inner end portion is fixed to the rotating member, and the outer end portion is extended outside the eyepiece tube through a guide groove extending along the circumferential direction of the eyepiece tube. Control lever,
Rotating operation of the rotating member that rotates around the optical axis of the eyepiece lens together with the operating lever when the operating lever rotates in the circumferential direction of the eyepiece tube along the guide groove A conversion mechanism for converting the lens holder into an axial movement operation of the lens holder;
An eye shade supported so as to be able to project and retract along the lens holder with respect to the eyepiece;
A slide member supported so as to be movable along the axial direction of the optical axis of the eyepiece, and having a front end fixed to the eye shade;
An operation unit for adjusting the height of the eye shade disposed at a position away from the eye shade in the optical axis direction of the eyepiece in the eyepiece tube;
A drive mechanism that slides the slide member along the optical axis of the eyepiece lens by operating the operation unit;
A sterilization cover attached to the microscope body and covering the entire microscope body;
An opening formed in the sterilization cover and opening a portion corresponding to the eyepiece tube in the eyepiece;
A drape fixture for fixing the vicinity of the opening of the sterilization cover to the eyepiece tube;
Comprising
The operation lever for adjusting the diopter and the operation unit for adjusting the height of the eyeshade are separated from the lens holder and the eyeshade in the optical axis direction of the eyepiece, and the sterilization cover is attached. A microscope apparatus for operation characterized in that the microscope apparatus is arranged inside the portion .

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