JP3162586U - Monocular ophthalmoscope - Google Patents

Abstract

Provided is a monocular ophthalmoscope which adjusts the position of an optical axis and holds the optical axis at the adjusted position without holding it by hand. A light emitting unit that emits light forward is connected to a mounting body that is mounted on a head by a connecting mechanism so that the position of the light emitting unit can be adjusted. The connection mechanism 4 includes an arm 5 having one end attached to the mounting body 2 at the center in the left-right direction of the head and the light emitting unit 3 attached to the other end, and attachment of one end of the arm 5 A rotation support portion that rotatably supports the first axis extending in the front-rear direction of the head and holds the arm 5 at the rotation stop position, and the arm 5 provided at least in the middle of the arm 5. And a universal joint 7 that can be bent three-dimensionally and can maintain a bent state, and the light emitting portion 3 can be moved to a symmetrical position around the center in the left-right direction of the head and at least vertically Be able to move left and right and move back and forth on the head. [Selection] Figure 2

Description

  The present invention relates to a monocular ophthalmoscope used when, for example, inspecting the inside of an eyeball by irradiating the eyes of a subject such as a patient with light.

  There are several types of ophthalmoscopes that are used when examining the inside of the eyeball, and one of them is a monocular ophthalmoscope that is used when observing the fundus irradiated with light in a reverse image. Is known (for example, see Patent Document 1). This ophthalmoscope is used so that the examiner performing the examination can hold it with his / her hand, and the irradiation light from the ophthalmoscope is emitted from the pupil of the subject such as the patient to the retina. The fundus examination is performed while the examiner visually observes the eyes of the examinee while holding the optical lens.

Japanese Utility Model Publication 2-74006

By the way, when examining the inside of the eyeball irradiated with light from the ophthalmoscope as described above, the fundus examination is performed by adjusting the positions of the examiner's visual axis and the optical axis of the ophthalmoscope. Since the adjustment is mainly performed by moving the optical axis, that is, the ophthalmoscope, if the ophthalmoscope is hand-held, the optical axis can be easily moved to a position where the examiner can easily see. However, since the hand is closed to hold the ophthalmoscope by hand, both hands are closed because the other hand has a condensing lens. The procedure could not be performed.
The problem to be solved by the present invention is to adjust the position of the optical axis and hold the optical axis at the adjusted position without having to hold it by hand.

  In order to solve the above problems, a monocular ophthalmoscope according to the present invention is connected to a mounting body mounted on at least the front surface of a human head with a connecting mechanism so that the position of a light emitting unit that emits light forward can be adjusted. When the attachment mechanism is mounted on the head, the connecting mechanism has one end attached to the mounting body at the center in the left-right direction of the head when viewed from the front. A linearly extending arm to which the light emitting part is attached to the other end, and an attachment of one end of the arm to be supported at least at a first axis extending in the front-rear direction of the head so as to be rotatable and at a rotation stop position A rotating support portion for holding the arm; and a universal joint provided at at least two locations along the arm so that the arm can be bent three-dimensionally and maintain a bent state. On the head, It is characterized in that it can be moved to a symmetrical position around the center of the left and right direction of the head, and can be moved at least up and down and left and right in the vicinity of the human eye and can be moved in the front and rear direction of the head. .

  In this way, the light emitting unit is connected to the mounting body mounted on the human head by the arm, and one end of the arm is rotatably and holdably attached to the mounting body, and at least 2 in the middle of the arm. Since a universal joint that can be bent three-dimensionally and maintains the bent state is provided at the location, the light emitting portion is viewed from the front, with a symmetrical position or a human Since it can be moved up and down, left and right in the vicinity of the eyes and in the front and rear direction of the head, the position of the optical axis can be adjusted, and the adjusted position of the optical axis can be held without having to hold it by hand.

  In this case, the connection mechanism can be detachably attached to the mounting body. In this case, the length from the first axis to the optical axis of the light from the light emitting unit when the first axis is located in the center between the human eyes and the arm is linearly extended is defined as Can be formed with a dimension that is equal to or greater than the length from the center of both eyes to the center of one eye. Further, in this case, the light source of the light emitting portion may be an LED, and the universal joint may be a ball joint including an aluminum ball and a synthetic resin receiving portion that rotatably supports the ball in three dimensions. it can. The ball joint can be supported in a state where the ball is sandwiched by a receiving portion made of synthetic resin having elasticity. Further, in this case, the mounting body can be a mounting frame that is mounted on a person's forehead, temples, and temporal region and can be put on an ear.

  Further, in this case, the connecting mechanism includes a second shaft extending in the left-right direction of the head, and is suspended so as to be rotatable only about the second shaft and held at the rotation stop position, and the first shaft is used as the shaft. And a box provided with a rotation support part at the bottom so that one end of the arm is rotatably supported, and the light emitting part is rotated upward with respect to the mounting body via the box, Therefore, the light emitting unit can be moved above the human eye when viewed from the side. Moreover, the switch box is rotated upward beyond the desired angle in the ON state in which light can be irradiated from the light emitting unit from the state where the box is suspended to the position rotated by the desired angle upward. Then, it is possible to provide a switch mechanism for turning off the light that is not irradiated from the light emitting unit. The desired angle is preferably 20 ° or more.

  According to the present invention, while adjusting the position of the optical axis, it is possible to hold the optical axis at the adjusted position without having to hold it by hand.

1 is a perspective view showing a monocular ophthalmoscope according to an embodiment of the present invention. It is a partial cross section side view which shows the principal part of the ophthalmoscope of this embodiment. In addition, the hatching of the cross-sectional part in FIG. 2 is abbreviate | omitted. It is a front view which shows the principal part of the ophthalmoscope of this embodiment. It is a perspective view which shows that the light emission part can be moved left-right symmetrically after mounting | wearing the person's head with the ophthalmoscope of this embodiment. It is a perspective view which shows that the light emission part can be turned after mounting | wearing the person's head with the ophthalmoscope of this embodiment. It is a perspective view which shows that the light emission part can be moved up and down after mounting | wearing the person's head with the ophthalmoscope of this embodiment. It is a perspective view which shows that the light emission part can be moved back and forth, after mounting | wearing the person's head with the ophthalmoscope of this embodiment. It is a perspective view which shows that after attaching the ophthalmoscope of this embodiment to a person's head, a light emission part can be rotated up and down with a switch box. BRIEF DESCRIPTION OF THE DRAWINGS It is a front view for demonstrating the relationship between the ophthalmoscope of this embodiment, and eyes, (a) is a figure which shows the state which positioned the light emission part above the vicinity of eyes, (b) is centering on the light emission part. The figure which shows the state which positioned, (c) is a figure which shows the state which positioned the light emission part below the vicinity of eyes. It is the front view which showed the range which can operate | move the ophthalmoscope of this embodiment. BRIEF DESCRIPTION OF THE DRAWINGS It is a front view for demonstrating the relationship between the ophthalmoscope of this embodiment, and an eye, (a) is a figure which shows the state which positioned the light emission part under the vicinity of a human eye with the space | interval of both eyes minimum, (b). Is a diagram showing a state in which the light emitting part is positioned below the vicinity of the eyes of the average person, and (c) is a state in which the light emitting part is positioned below the vicinity of the person's eyes having the largest distance between the eyes. FIG. It is a front view which shows the state which folded the arm of the ophthalmoscope of this embodiment. It is a figure which shows the principal part of the ophthalmoscope of another example of this embodiment, (a) is a front view, (b) is a side view.

  Embodiments of a monocular ophthalmoscope according to the present invention will be described below with reference to the accompanying drawings. As shown in FIGS. 1 to 8, an ophthalmoscope 1 according to an example of this embodiment includes a connecting mechanism 4 that can adjust the position of a light emitting unit 3 that irradiates light to a mounting body 2 that is mounted on a human head 11. It is a monocular type connected with.

  The wearing body 2 is not particularly limited as long as it is attached to at least the front surface of the human head 11, and may be a frame, a band type, a hat-like covering, etc. A frame 20 is preferred. The mounting frame 20 is, for example, mounted on a person's forehead, temples, and temporal head 11 and put on an ear. The mounting frame 20 is connected to the front 21 located on the front of the person's forehead and the ends of the front 21 that are bent at substantially right angles via hinges 23, and is attached to the temple and the temporal region. A temple 22 to be put on the ear, and a portion that is provided on a mounting portion 24 that extends downward when the mounting frame 20 is mounted on the head 11 in a direction orthogonal to the front 21 from the center of the front 21 and supports the mounting frame 20 with nose muscles And a pad 25 which is also a nose pad. The front 21, the temple 22, and the attachment portion 24 of the mounting frame 20 are made of, for example, synthetic resin. When the mounting frame 20 is mounted on the head 11, the mounting portion 24 is integrally provided with a pair of support pieces 87 having elasticity that extends forward from the face and is spaced from each other. The pair of support pieces 87 are provided with through holes on the same axis.

  The light emitting unit 3 emits light forward from the vicinity of the front surface of the head 11 and includes a cylindrical lens barrel 30. An LED substrate 32 and a condenser lens 33 on which an LED 31 as a light source is mounted are provided in the vicinity of the base end, which is one end in the lens barrel 30. Two projection lenses 35 are provided in the distal end portion which is the other end portion of the lens barrel 30 with an interval in the axial direction. A diaphragm mechanism 36 is provided between the condenser lens 33 and the projection lens 35 of the lens barrel 30. The diaphragm mechanism 36 may be formed in any manner. For example, a cylindrical diaphragm ring 37 is rotatably provided on the outer periphery of the lens barrel 30, and the diaphragm of the ophthalmoscope 1 is adjusted by rotating the diaphragm ring 37. It is configured to be.

  The coupling mechanism 4 couples the light emitting unit 3 to the mounting body 2 so that the position of the light emitting unit 3 can be adjusted. The coupling mechanism 4 has an arm 5 whose both ends are attached to the mounting frame 20 and the light emitting unit 3, and a rotation support unit that can rotate the end of the arm 5 on the side of the mounting body 2 and hold it in a rotating position. 6 and a universal joint 7 provided in the middle of the arm 5 so as to be able to bend the arm 5 three-dimensionally and maintain the bent state. The arm 5 may be directly attached to the mounting frame 20, but is preferably attached to the mounting frame 20 via the switch box 8 which is a box. That is, it is preferable that the coupling mechanism 4 has a second shaft extending in the left-right direction of the head 11 and a switch box 8 that is suspended only around the second shaft and held at the rotation stop position.

  A mounting plate 86 made of synthetic resin, for example, polyacetal, is mounted on the mounting portion 24 of the mounting frame 20 in a fixed state. The mounting plate 86 is integrally provided with a pair of support pieces 87 spaced forward. The pair of support pieces 87 are provided with through holes on the same axis. The switch box 8 is formed in a rectangular box shape with aluminum, for example. An insertion hole is provided near the corner on the mounting portion 24 side above the switch box 8. The switch box 8 is disposed between the pair of support pieces 87 in a state where the through holes of the pair of support pieces 87 and the insertion holes of the switch box 8 are aligned, and serves as a second shaft extending in the left-right direction of the head 11. The second pin 16 is sequentially passed through the through hole, the insertion hole, and the through hole, and the tip of the second pin 16 is tightened or caulked with a nut. Thus, the switch box 8 is suspended from the second pin 16 and supported so as to be rotatable upward from the suspended state around the second pin 16 as an axis.

  The angle at which the switch box 8 can be rotated from the suspended state is not particularly limited. However, when the light emitting unit 3 is rotated upward with respect to the mounting body 2, it is located above the human eye when viewed from the front. It is preferable that the angle is such that the light emitting unit 3 can move upward from the visual axis when viewed in FIG. 1. In the present embodiment, the angle is preferably 90 ° or more, and more preferably 90 to 120 °. Specifically, for example, when the switch box 8 is rotated 90 ° from the suspended state, the switch box 8 can be rotated from the suspended state of the switch box 8 by contacting the mounting portion 24 or a stopper provided on the mounting portion 24. The angle may be set to 90 °. Further, the width of the switch box 8 (the length of the head portion 11 in the left-right direction) is formed with substantially the same dimension as the distance between the pair of support pieces 87. The switch box 8 can be rotated about the second pin 16, and the frictional force that can be held at a position where the rotation is stopped acts between the switch box 8 and the pair of support pieces 87. Adjustment is made when the tip of the 2-pin 16 is squeezed or crimped with a nut.

  The switch box 8 is provided with a switch mechanism 80. The switch mechanism 80 is in an ON state in which light can be emitted from the light emitting unit 3 from a suspended state in which the switch box 8 is suspended to a position rotated upward by a desired angle, and the switch box 8 is moved upward beyond the desired angle. In the rotated state, the light emitting unit 3 is turned off so that no light is irradiated. The configuration of the switch mechanism 80 is not particularly limited, and includes, for example, a cam 81, a lever 83, and a switch plate 84.

  The cam 81 has a substantially arc-shaped operating piece 82 and is rotatably provided in the switch box 8, and the operating piece 82 advances and retreats from the opening 8 a on the back surface, which is the surface on the mounting portion 24 side of the switch box 8 by the rotation. It is possible. The lever 83 is formed in a substantially linear shape and is provided rotatably in the switch box 8. In the vicinity of one end of the lever 83, a contact portion 83a that contacts the cam 81 is formed. At the other end of the lever 83, the operating part of the limit switch is pushed down. Further, one end of a spring 85 such as a tension coil spring, which is an urging means, is attached between one end of the lever 83 and the rotating shaft of the lever 83. The other end of the spring 85 is attached to a switch plate 84 fixed in the switch box 8. Thus, the lever 83 biases the cam 81 in a direction in which the operating piece 82 protrudes from the opening 8 a on the back surface of the switch box 8 by the biasing force of the spring 85.

  Further, when the switch box 8 is in the suspended state, the tip of the operating piece 82 comes into contact with the mounting portion 24 (or the mounting plate 86), and most of the operating piece 82 is accommodated in the switch box 8, and the second from the suspended state. When the pin 16 is rotated upward about the shaft, the actuating piece 82 gradually protrudes from the opening 8a on the back surface of the switch box 8 while the tip is in contact with the mounting portion 24 by the urging force of the spring 85 along with the rotation. When the rotation angle reaches a desired angle, the distal end of the operating piece 82 moves away from the mounting portion 24, and the operating piece 82 stops rotating with respect to the switch box 8 and has the same length protruding from the opening 8a on the back surface. It becomes a state. Therefore, a limit switch is provided on the switch plate 84 so that when the operating piece 82 is at a desired angle with respect to the mounting portion 24, the light is not irradiated from the light emitting unit 3, and the operating piece 82 comes into contact with the mounting portion 24. The cam 81 rotates against the biasing force of the spring 85 and the length of the operating piece 82 protruding from the opening 8a on the back surface of the switch box 8 is shortened, that is, the switch box 8 is moved upward from the suspended state. The light can be irradiated from the light emitting unit 3 up to a position rotated by a desired angle. The desired angle, that is, the switching angle of the switch is not particularly limited. However, considering that the light from the light emitting unit 3 is not interrupted when the position of the lens barrel 30 is adjusted, that is, the irradiation is continued. 5 ° or more, preferably 10 ° or more, more preferably 20 ° or more, even more preferably 30 ° or more, even more preferably 45 ° or more, and most preferably the light emitting portion 3 is above the human eye when viewed from the front. The angle at which it is positioned, for example 90 ° in this embodiment. Thus, when setting the switching angle of the switch, the switch box 8 is rotated by, for example, 90 ° from the suspended state and abuts against the mounting portion 24 or the stopper provided on the mounting portion 24 so that the rotation of the switch box 8 is restricted. When the switch box 8 is configured, the switch may be switched, that is, the switch may be turned off when the switch box 8 comes into contact with the mounting portion 24 or the stopper.

  One end of the arm 5 is attached to the bottom surface of the switch box 8. The attachment of one end of the arm 5 is performed by the rotation support portion 6, and if the first pin 65, which is the first shaft extending in the front-rear direction of the head 11, can be rotatably supported on the shaft and held in the rotation position, Although it may rotate in other directions, it is preferable that the arm 5 rotate only about the first pin 65 as an axis. A rotation support piece 61 constituting the rotation support portion 6 is formed to extend from the bottom surface of the switch box 8 in a direction orthogonal to the bottom surface. The rotation support piece 61 is formed in a flat plate shape whose width direction is parallel to the left-right direction of the head 11 when the mounting frame 20 is mounted on the head 11. The rotation support piece 61 is provided with a hole. One end of the arm 5 is attached to the rotation support piece 61 so as to be rotatable and held at the rotation position.

  The arm 5 is composed of, for example, a first arm 51, a second arm 52, and a third arm 53, and these three arms 51, 52, 53 are respectively connected by a ball joint 70 as a universal joint 7. . That is, two ball joints 70 are provided in the middle of the arm 5. The number of ball joints 70 provided in the middle of the arm 5 may be three or more, but two is preferable as shown in the figure. The universal joint 7 is not limited to the ball joint 70 as long as the arm 5 can be bent three-dimensionally and can maintain the bent state. Is preferred.

  The first arm 51 is made of a synthetic resin, for example, polyacetal and has an elongated shape with a substantially rectangular cross section. A concave portion 62 having a concave cross section extending in a direction orthogonal to the longitudinal direction of the first arm 51 is formed at one end of the first arm 51. The recess 62 is for inserting the rotation support piece 61. The width of the concave portion, that is, the length in the thickness direction of the rotation support piece 61 is formed to be thicker than the thickness of the rotation support piece 61, for example, slightly thicker. One end of the first arm 51 is formed as a pair of rotatable base pieces 51c having elasticity by the recess 62 and being flexible. The pair of rotating base pieces 51c are provided with coaxial holes. In a state where the rotation support piece 61 is inserted into the recess 62 between the pair of rotation base pieces 51c and the holes of the pair of rotation base pieces 51c are aligned with the holes of the rotation support piece 61, the first pin 65 is inserted into the three pins. A nut 66 is screwed into the tip of the first pin 65 through the holes. As a result, the first arm 51 is supported so as to be rotatable about the first pin 65 with respect to the rotation support piece 61. Further, the first arm 51 is formed so as to rotate in a range of 90 ° or more, for example, 90 ° in the left-right direction when viewed from the front from the state where it is suspended from the first pin 65 with respect to the first pin 65. Is preferred. Further, the first arm 51 can be rotated with respect to the rotation support piece 61 about the first pin 65, and when the rotation is stopped, a frictional force that can be held at the position is a pair of rotation bases of the first arm 51. The tightening of the first pin 65 and the nut 66 is adjusted so as to act between the piece 51 c and the rotation support piece 61.

  At the other end of the first arm 51, a receiving portion 71 having a concave cross section formed in substantially the same manner as the concave portion 62 is formed. The other end portion of the first arm 51 is formed as a pair of receiving portion pieces 51 d having elasticity by the receiving portion 71. Ball receiving recesses 72 are respectively formed on the inner surfaces of the pair of receiving portion pieces 51d forming the receiving portion 71 facing each other. In the illustrated example, the ball receiving recess 72 is formed in a concave shape in cross section, but may be formed in a spherical shape with the same R as the spherical surface R of the ball described later. The first arm 51 is composed of two first arm A parts 51a and first arm B parts 51b which are substantially divided into two by a recess 62 and a receiving part 71. These parts 51a and 51b are screws such as screws 57, for example. The members are detachably attached to each other.

  The second arm 52 is formed, for example, in a rod shape extending in a straight line having a circular cross section. For example, spherical balls 73 and 74 having the same diameter constituting the ball joint 70 are integrally formed at both ends of the second arm 52, respectively. The second arm 52 is made of metal such as aluminum. One ball 73 of the second arm 52 is rotatably supported in a state of being sandwiched by the ball receiving recesses 72 of the pair of receiving portions 71 of the first arm 51, and the ball joint 70 is configured. That is, the first arm 51 and the second arm 52 are connected to each other by the ball joint 70 so as to be able to be bent three-dimensionally. Further, the second arm 52 can be rotated, that is, bent with respect to the first arm 51 around the ball 73, and when the bending is stopped, a frictional force that can be held at that position is received by the pair of first arms 51. The tightening by the screw members of the two parts 51a and 51b forming the first arm 51 is adjusted so as to act between the part 51d and the ball 73.

  The third arm 53 includes an elongated flat plate-like third arm A part 53a and an L-shaped third arm B part 53b. These parts 53a and 53b are made of an elastic synthetic resin such as polyacetal, and the third arm B part 53b is attached to a substantially central portion of the third arm A part 53a by a screw member such as a screw 58, so that the third An arm 53 is formed. At one end of the third arm 53, a receiving portion 75 having a concave cross section is formed by the third arm A part 53a and the third arm B part 53b. A ball receiving concave portion 76 having a concave cross section is formed on the inner surfaces of the one end of the third arm A part 53a and the end of the third arm B part 53b that form the receiving portion 75 facing each other. The receiving portion 75 and the ball receiving recess 76 are formed in substantially the same shape as the receiving portion 71 and the ball receiving portion 72 of the first arm 51. Accordingly, the other ball 74 of the second arm 52 is rotatably supported in a state of being sandwiched by the two ball receiving recesses 76 of the receiving portion 75 of the third arm 53, and the ball joint 70 is configured. That is, the second arm 52 and the third arm 53 are connected to each other by the ball joint 70 so as to be able to be bent three-dimensionally. Further, the third arm 53 can be rotated, that is, bent with respect to the second arm 52 around the ball 74, and when the bending is stopped, a frictional force that can be held at that position is generated between the ball 74 and the third arm 53. The tightening by the screw members of the two parts 53a and 53b forming the third arm 53 is adjusted so as to act between the third arm A part 53a and the third arm B part 53b.

  Further, in the vicinity of the other end of the surface of the third arm A part 53a on the side where the third arm B part 53b is attached, the base end of the lens barrel 30 is perpendicular to the surface of the lens barrel 30. For example, it is detachably attached by a screw member. The third arm 53 and the lens barrel 30 are formed in a substantially L shape. The length of the third arm 53 in the longitudinal direction, that is, the length from the center of the ball 74 to the axis of the lens barrel 30, and the length of the first arm 51 in the longitudinal direction, that is, the rotation axis of the first arm 51, that is, the first axis. The lengths from the axis of the 1 pin 65 to the center of the ball 73 may be different dimensions, but are preferably formed with the same dimensions. Further, the lengths of the first arm 51 and the third arm 53 in the longitudinal direction are not particularly limited, but it is preferable that the sum of these lengths is formed to have the same dimension as the average length between human eyes. The length of the second arm 52 in the longitudinal direction, that is, the length between the axes of the balls 73 and 74 is preferably shorter than the length of the first arm 51 in the longitudinal direction. In a folded state (see FIG. 12), the power cable 18 (described later) is formed so as not to be sandwiched between the other end of the first arm 51 and one end of the third arm 53. It is preferable.

  The first arm 51, the second arm 52, and the third arm 53 are connected by a ball joint 70 to extend in the longitudinal direction of the entire arm 5, that is, the first arm 5 relative to the rotation support piece 61. The length from the axis of the pin 65 to the axis of the lens barrel 30 is not particularly limited as long as the lens barrel 30 can be positioned above and below the center of the human eye, that is, near the black eye. It is preferable that the distance between the eyes is not less than half the dimension of the distance between the eyes, and the distance between the eyes is the longest from the center of the eyes of the person to the center of one eye (the middle of the black eye). Most preferably, it is formed with a dimension that is less than the length from the center of both eyes to the center of one eye.

  A power cable 18 that supplies power for causing the LEDs 31 to emit light is connected to the lens barrel 30 of the light emitting unit 3. The power cable 18 is wired along the temple 22 from the front 21 of the mounting frame 20 via the switch box 8, and power supply to the lens barrel 30 is controlled by a limit switch in the switch box 8. The power cable 18 further extends from the vicinity of the tip of the temple 22 and is connected to a power supply source. The supply source is provided with a power switch for switching ON / OFF of power supply.

  In order to perform a fundus inversion test using the ophthalmoscope 1, first, the mounting frame 20 is mounted on the head 11 like glasses. After the mounting frame 20 is mounted, the power switch is switched so that power is supplied to the light emitting unit 3. Thereby, since light is emitted from the lens barrel 30 using the LED 31 as a light source, the position of the lens barrel 30, that is, the position of the light source is adjusted so that the irradiation light is emitted from the pupil of the subject such as a patient to the fundus, that is, the retina. To do. After the position of the lens barrel 30 is adjusted, the fundus examination is performed while the examiner visually observes the eyes of the subject to be examined while holding the condenser lens with one hand. At this time, after positioning the lens barrel 30 at a position where the examiner can easily see, the lens barrel 30 is held at that position, so there is no need to hold the ophthalmoscope 1 by hand. For this reason, since one hand which does not have a condensing lens becomes free, procedures, such as scleral compression, can be performed to a test subject with the hand.

  In adjusting the position of the lens barrel 30, it is desirable that the optical axis and the examiner's visual axis are appropriately close to each other. Normally, the lens barrel 30 is located below the vicinity of the eyes as viewed from the front. The position adjustment of the lens barrel 30 is performed by moving the lens barrel 30 while grasping it by hand. At this time, the lens barrel 30 is connected to the mounting frame 20 via the arm 5, and one end of the arm 5 is centered on the first pin 65 with respect to the mounting frame 20 (actually the switch box 8). Two ball joints 70 that rotate and can be bent three-dimensionally are provided in the middle of the arm 5. In this way, the lens barrel 30 is connected to the arm 5 that can be bent with respect to the mounting frame 20 by the three axes of the first pin 65 and the two ball joints 70. For example, FIG. As shown in FIG. 10, it can be easily positioned at a desired position within a range surrounded by a curve or in the vicinity of the eyes, and fine adjustment can be performed. As a result, when a fundus examination is performed, it is usually easy to position the lens barrel 30 below the vicinity of the examiner's eyes, and the fundus examination is facilitated.

  In addition, the fundus examination can be performed even when the lens barrel 30 is positioned above or beside the eye of the examiner, so that the fundus examination can be performed by changing the light irradiation direction, that is, at various light irradiation angles. In this case, by positioning the lens barrel 30 above the vicinity of the examiner's eyes, the left and right and lower visual fields of the eyes are not obstructed by the light emitting unit 3. For this reason, even during the fundus examination, for example, the paper on the desk can be filled in with a pen or the like, so that the fundus examination can be performed quickly.

  The position of the arm 5, that is, the first arm 51 with respect to the switch box 8 is held by a frictional force generated between the rotation support piece 61 of the switch box 8 and the pair of rotation base pieces 51 c of the first arm 51. By the way, when holding the position of the other metal with respect to one metal with the frictional force which arises between metals, the thing using the clamp | tightening by a screw member is known. In this case, in order to change the position of the other metal with respect to one metal, the screw member is loosened and the position of the other metal is changed and then the screw member is tightened. It had to be loosened and tightened with members, which was troublesome and could not be performed quickly. On the other hand, in this embodiment, the position of the first arm 51 is maintained by the frictional force between the aluminum rotation support piece 61 and the elastic synthetic resin rotation base piece 51c. When a force is applied to the first arm 51 so that the rotation base piece 51c rotates with respect to the rotation support piece 61, the rotation base piece 51c bends against the elastic force, and the first arm 51 moves to the first pin 65. Rotate around the axis. When the rotation is stopped, the rotation base piece 51c is no longer bent by the elastic force, and the rotation base piece 51c, that is, the first arm 51 is moved against the rotation support piece 61 by the frictional force between the rotation support piece 61 and the rotation base piece 51c. Held in that position. Accordingly, the first arm 51 can be rotated with respect to the rotation support piece 61 and held at that position without changing the frictional force between the rotation support piece 61 and the rotation base piece 51c.

  Similarly, in the two ball joints 70, the balls 73 and 74 are made of aluminum, and the receiving piece 51d, the third arm A part 53a, and the third arm B part 53b forming the receiving parts 71 and 75 are elastic. The second arm 52 is rotated with respect to the first arm 51, and the third arm 53 is rotated with respect to the second arm 52 without changing the frictional force, and It can be held at that stop position. Therefore, since the position of the lens barrel 30 can be changed only by moving the lens barrel 30 relative to the mounting frame 20, the position adjustment of the lens barrel 30 is easy, and a fundus examination can be performed quickly.

  In addition, since the axis of the first pin 65 is located at the center of the head 11 in the left-right direction, the lens barrel 30 can be positioned at a symmetrical position around the center of the head 11 in the left-right direction. it can. For this reason, the dominant eye differs depending on the person on either the left or right side, but since the lens barrel 30 can be positioned at a symmetrical position, it is possible to perform the fundus examination in the same way even for people with different dominant eyes. Yes (see FIG. 4).

  The distance between the eyes of the person is not constant and varies depending on the individual, but the length of the arm 5 is longer than the distance from the center of both eyes of the person with the largest distance between the eyes to the center of one eye (pupil center). As shown in FIG. 11, the lens barrel 30 can be positioned in substantially the same state below the vicinity of the eyes, as shown in FIG. Further, since two ball joints 70 are provided in the middle of the arm 5, as shown in FIG. 7, the lens barrel 30 can be moved in the substantially optical axis direction which is the substantially axial direction. Further, since the second arm 52 and the third arm 53 are connected by the ball joint 70, the lens barrel 30 can be turned as shown in FIG. Further spread and easy to perform fundus examination. Therefore, the ophthalmoscope 1 according to the present embodiment can move the lens barrel 30 back and forth, up, down, left and right, and can turn, so that the degree of freedom of adjustment of the lens barrel 30, that is, the optical axis is high, that is, the optical axis at a position where the examiner can easily see Can be moved freely.

  Further, since the light emitting unit 3 uses the LED 31 as a light source, the light emitting unit 3 is light and small in size. Therefore, the mounting frame 20 having substantially the same shape as the eyeglass frame can be used as the mounting body 2 to which the light emitting unit 3 is attached. For this reason, since the ophthalmoscope 1 can be easily attached to the head 11 and is lightweight even if it is attached to the head 11, the neck or the like is hard to get tired even when used for a long time, and there is a feeling of fatigue. Few. Since the first arm 51 and the third arm 53 are made of synthetic resin and the second arm 52 including the two balls 73 and 74 is made of aluminum, the weight can be further reduced. As a result, the weight of the entire ophthalmoscope 1 can be reduced to, for example, about 60 g, so that fatigue can be further reduced.

  When the ophthalmoscope 1 is not used immediately after use, for example, the first arm 51 is gripped, and the light emitting unit 3, the arm 5 and the switch box 8 are integrally rotated around the second pin 16 as an axis. The unit 3 is flipped up so that the light emitting unit 3 is positioned above the human eye when viewed from the front (see FIG. 8). As a result, the field of view of the examiner is expanded, so that the ophthalmoscope 1 can perform conversations and explanations with the examinee and the like, and filling in the medical record, etc., without being in the way. When the ophthalmoscope 1 is used from the state where the light emitting unit 3 is flipped up, the light emitting unit 3 that is flipped up is rotated (lowered) around the second pin 16 in the opposite direction, that is, downward. The ophthalmoscope 1 can be used by being in the hanging state as the position. Therefore, when the ophthalmoscope 1 is not used, the light-emitting unit 3 can be moved up and positioned above the human eye, so that the light-emitting unit 3 is not obstructed while the ophthalmoscope 1 is attached to the head 11. It is convenient because you can work.

  Further, when the first arm 51 is grasped and the light emitting unit 3 is flipped up and down, the first arm 51 rotates only with the first pin 65 as an axis with respect to the switch box 8, so that the light emitting unit 3 is flipped up. The position of the light emitting unit 3 that is lowered afterwards, that is, the position of the lens barrel 30 with respect to the eyes, is the same position as before the flip-up. For this reason, when the fundus examination is performed and the ophthalmoscope 1 is flipped up and then lowered to perform another fundus examination, the position of the optical axis relative to the examiner's visual axis is the same as before the flip-up. Since it is not necessary to adjust the position of the optical axis of the ophthalmoscope 1 with respect to the visual axis of the examiner again, the subsequent fundus examination can be performed quickly.

  Further, the switch box 8 is provided with a switch mechanism 80 that switches between an on state in which light can be emitted from the light emitting unit 3 and an off state in which light is not emitted from the light emitting unit 3 by flipping the ophthalmoscope 1 up and down. Therefore, when the ophthalmoscope 1 is not used, it can be turned off simply by flipping up the ophthalmoscope 1, so that power can be wasted and switching work of the power switch is unnecessary. Further, the on / off switching by the switch mechanism 80 is performed at a position rotated by 5 ° or more, for example, 30 °, 45 °, or 90 ° upward from a suspended state in which the light emitting unit 3 is rotated about the second pin 16. Thus, when the lens barrel 30 is moved in the substantially axial direction and the position of the lens barrel 30 is adjusted, light can be transmitted without interruption. In other words, when the switch box 8 is turned off from the state where the switch pin 8 is suspended from the second pin 16 slightly, the lens barrel 30 is moved in the substantially axial direction so that the light irradiation is not performed. When the position of the lens barrel 30 is adjusted, the switch box 8 may rotate upward from the suspended state about the second pin 16 as an axis. In this case, if the light is no longer irradiated, it is difficult to adjust the position of the lens barrel 30 because the light irradiation position is unknown. Further, even when the light-emitting unit 3 is accidentally touched while the ophthalmoscope 1 is in use and the light-emitting unit 3 rotates around the second pin 16, no light is irradiated, and the inspection is interrupted or the inspection is restarted from the beginning. In some cases, the ophthalmoscope 1 of the present embodiment does not stop irradiating light in that case.

  Further, by folding both the temples 22 on the front 21 side through the hinges 23 and folding the arm 5 as shown in FIG. In addition, the housing case can be reduced in size and carried easily. Further, as shown in FIG. 10, since the lens barrel 30 can be positioned at a desired position within the range surrounded by the curve, the ophthalmoscope 1 of the present embodiment is not limited to the fundus examination, and other examinations, affected areas, etc. Therefore, it can be used for observation of the image and the like.

  FIG. 13 is a diagram illustrating another example of the ophthalmoscope of the present embodiment. The difference of the ophthalmoscope 100 from the ophthalmoscope 1 is the configuration of the ball joint 70 and the shape of the arm 5 by the configuration of the ball joint 70, and the other configurations are the same as those of the ophthalmoscope 1. That is, the shape of one end of the first arm 151 and the shape of the other end of the third arm 153 are the same as those of the first arm 51 and the third arm 53, but the other end of the first arm 151 is the same. And one end of the third arm 153 are respectively connected to balls 173 and 174 made of aluminum via a connecting portion.

The second arm 152 is composed of two parts made of a synthetic resin, such as polyacetal, which has the elasticity of an elongated flat plate-like second arm A part and second arm B part, and these two parts are attached by, for example, screw members. It is formed with. Receiving portions 171 and 175 having a concave section extending in the direction orthogonal to the longitudinal direction of the second arm 152 are formed at both ends of the second arm 152 by the second arm A part and the second arm B part, respectively. . Ball receiving recesses 172 and 176 are respectively formed on the inner surfaces of the third arm A part and the third arm B part that form the receiving portions 171 and 175 at opposite ends thereof. Thereby, the balls 173 and 174 at the other end of the first arm 151 and the one end of the third arm 153 are respectively in contact with the two ball receiving recesses 172 of the receiving portions 171 and 175 at both ends of the third arm 153, respectively. 176, and supported so as to be three-dimensionally rotatable. That is, the first arm 151 and the second arm 152 and the second arm 152 and the third arm 153 can be bent three-dimensionally by the ball joints 70. In addition, the second arm 152 with respect to the first arm 151 and the third arm 153 with respect to the second arm 152 can be rotated or bent around the respective balls 173 and 174, respectively, and when the bending is stopped, Tightening by the screw members of the two parts so that the frictional force that can be held in position acts between the balls 173 and 174 and both ends of the third arm A part and the third arm B part forming the second arm 152, respectively. Is to be adjusted.
Even if the ball joint 70, the first arm 151, the second arm 152, and the third arm 153 are formed in this manner, the ophthalmoscope 100 operates in substantially the same manner as the arm 5 described above. Has the same effect.

  In the above-described embodiment, the coupling mechanism 4 is attached to the mounting body 2 in a fixed state. However, the present invention is not limited to this, and the coupling mechanism 4 may be detachably attached to the mounting body 2. In this case, a portion from the mounting plate 86 to the light emitting unit 3 through the arm 5 is formed as one ophthalmoscope unit, and this ophthalmoscope unit has an attaching means for detachably attaching to the mounting body 2. preferable. The attachment means is not particularly limited as long as the ophthalmoscope unit, that is, the attachment plate 86 can be detachably attached to the mounting body 2. For example, clamping means such as a clip, fastening means using a screw member such as a screw, elastic force, etc. Engaging means using the can be used. As a result, one ophthalmoscope unit can be attached to a plurality of one type of attachment body 2 and can be attached to a plurality of attachment bodies 2 of different types. It will be expensive.

DESCRIPTION OF SYMBOLS 1 Ophthalmoscope 2 Mounted body 3 Light emission part 4 Connection mechanism 5 Arm 6 Rotation support part 7 Universal joint 8 Switch box 11 Head 16 Second pin 20 Mounting frame 30 Lens barrel 31 LED
65 1st pin 71 receiving part 73 ball 74 ball 75 receiving part 70 ball joint 80 switch mechanism

Claims (8)

A monocular ophthalmoscope in which a light emitting unit that emits light forward is connected to a mounting body that is attached to at least the front surface of a human head by a connecting mechanism so that the position of the light emitting unit can be adjusted.
When the attachment mechanism attaches the mounting body to the head, one end is attached to the mounting body at the center in the left-right direction of the head when viewed from the front, and the light emission is applied to the other end. The arm to which the portion is attached and the attachment of one end of the arm are supported so as to be rotatable about at least a first axis extending in the front-rear direction of the head and to hold the arm in the rotation stop position. A rotation support portion, and a universal joint provided at at least two locations in the middle of the arm and capable of bending the arm three-dimensionally and holding the bent state;
When the mounting body is mounted on the head, the light emitting unit can be moved to a symmetrical position around the center of the head in the left-right direction when viewed from the front, and at least up, down, left and right in the vicinity of the human eye And a monocular ophthalmoscope which is configured to be movable in the front-rear direction of the head.   The monocular ophthalmoscope according to claim 1, wherein the coupling mechanism is detachably attached to the mounting body. The first axis is located in a central portion between the eyes of the person;
The length from the first axis to the optical axis of the light from the light emitting unit when the arm is extended linearly is the length from the center of both eyes of the person with the largest distance between the eyes to the center of one eye. The monocular ophthalmoscope according to claim 1 or 2, wherein the monocular type ophthalmoscope is formed with a size larger than that. The light source of the light emitting unit is an LED,
The monocular system according to any one of claims 1 to 3, wherein the universal joint is a ball joint including an aluminum ball and a synthetic resin receiving portion that rotatably supports the ball in a three-dimensional manner. Ophthalmoscope.   The monocular ophthalmoscope according to claim 4, wherein the ball joint is supported in a state where the ball is held by a receiving portion made of a synthetic resin having elasticity.   The monocular ophthalmoscope according to any one of claims 1 to 5, wherein the wearing body is a wearing frame that is worn on the person's forehead, temples, and temporal region and put on an ear.   The coupling mechanism includes a second shaft extending in the left-right direction of the head, and is suspended so as to be rotatable only about the second shaft and held at a rotation stop position, and the first shaft is used only for the shaft. And a rotation support portion provided at a lower portion so that one end portion of the arm is rotatably supported, and the light emitting portion is rotated upward with respect to the mounting body via the box. The monocular ophthalmoscope according to any one of claims 1 to 6, wherein the light emitting unit moves above the human eye when viewed from the front. From the state in which the box is suspended to the position rotated upward by a desired angle, the switch box is rotated upward beyond the desired angle in the ON state where light can be emitted from the light emitting unit. The monocular ophthalmoscope according to claim 7, further comprising a switch mechanism configured to turn off the light emitting unit so that no light is emitted from the light emitting unit.

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