JP4436913B2 - Optometry equipment - Google Patents

Description

  The present invention relates to an optometry apparatus that subjectively examines the refractive power of an eye to be examined.

2. Description of the Related Art An optometry apparatus that has a pair of left and right lens chamber units having an examination window, and inspects the refractive power of the eye to be examined by switching various optical elements to the examination window. In this type of optometry apparatus, a slide mechanism that moves the left and right lens chamber units in the direction of the eye width in order to change the interval of the examination window in accordance with the distance between the pupils of the subject, and a near-field examination and addition power A convergence mechanism for converging the left and right lens chamber units is provided in order to match the convergence angle of the eye to be examined during examination (see Patent Document 1).
JP 2004-57740 A

  By the way, in the examination using the above optometry apparatus, when the subject places his face on the forehead of the optometry apparatus and puts his eyes on a predetermined position of the examination window, the nose of the examinee is in the left and right lens chamber units. Will be located between. At this time, in a subject whose back eyes and nose are high, the nose protrudes toward the examiner between the left and right lens chamber units. When examining such a subject, if the distance between the left and right lens chamber units is reduced in order to match the distance between the pupils, or if the left and right lens chamber units are congested, the lens chamber is placed on the subject's nose. There was a risk that the unit would come in contact and put a burden on the subject. If the examiner does not notice this and continues the examination as it is, the examination result becomes inaccurate.

  In view of the above problems, an object of the present invention is to provide an optometry apparatus that can accurately perform an examination without imposing a burden on the subject.

(1) In an optometry apparatus that has a pair of left and right lens chamber units and subjectively examines the refractive power of the eye to be examined by switching and arranging optical elements in the examination window.
Moving means for changing the distance between the left and right lens chamber units, command means for inputting a command signal for driving the moving means, and the face of the subject at a predetermined inspection position with respect to the left and right lens chamber units Detection means for detecting the position and outputting a detection signal; and control means for driving and controlling the moving means based on a command signal from the command means, wherein the detection signal is output from the detection means And control means for prohibiting a moving operation to narrow the interval between the left and right lens chamber units.
(2) In the optometry apparatus according to (1), there is provided release means for releasing control for prohibiting a movement operation in which the control means narrows the interval between the left and right lens chamber units.
(3) In an optometry apparatus that has a pair of left and right lens chamber units, and inspects the refractive power of the eye to be examined by switching and arranging optical elements in the examination window,
Moving means for changing the distance between the left and right lens chamber units, command means for inputting a command signal for driving the moving means, and the lens chamber unit is in contact with the subject's nose during the moving operation of the moving means A contact detection means for detecting this and outputting a detection signal; and a control means for driving and controlling the movement means based on a command signal from the command means, and when the detection signal is output from the contact detection means, Control means for stopping the moving operation of the moving means or drivingly controlling the moving operation of the moving means in a direction in which the interval between the left and right lens chamber units is widened.

  ADVANTAGE OF THE INVENTION According to this invention, the optometry apparatus which can test | inspect accurately can be provided, without giving a burden to a subject.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a schematic diagram illustrating the entire optometry system according to the present embodiment, and FIG. 2 is a schematic external view of the optometry apparatus according to the present embodiment as viewed from the examiner side (during near-field examination).

  Reference numeral 1 denotes an optometry apparatus body. The optometry apparatus body 1 includes a pair of left and right lens chamber units 60 and a moving unit 6 that supports the left and right lens chamber units 60 in a suspended manner. The moving unit 6 includes a slide mechanism that adjusts the distance between the left and right lens chamber units 60 in order to change the distance between the examination windows 61 in accordance with the distance between the pupils of the subject, and the convergence angle (hitting angle) of the left and right lens chamber units 60. The moving means 40 (refer FIG. 6) which has a convergence mechanism which adjusts a close angle | corner) is included inside.

  The optometry apparatus main body 1 is supported above the table 10 by a support arm 4 provided on the table 10. Reference numeral 11 denotes a vertical movement switch for moving the table up and down. By using this switch 11, the height position of the top plate of the table 10 is adjusted by a driving means (not shown) and the height of the optometry apparatus main body 1 is adjusted. Can be adjusted.

  Reference numeral 20 denotes an optotype presenting apparatus which is placed at a position away from the optometric apparatus main body 1 by a predetermined distance (for example, about 1 m) and is used for a distance examination (in FIG. 1, an internal schematic configuration is shown). The optotype presenting apparatus 20 includes an optotype presenting means 21 that presents various inspection targets within the apparatus, a beam splitter 22, a concave mirror 23, and the like. The light beam of the inspection target emitted by the target presenting means 21 is reflected by the concave mirror 23 after passing through the beam splitter 22. The target luminous flux reflected by the concave mirror 23 is reflected by the beam splitter 22 and travels toward the eye E through the window 24.

  Reference numeral 2 denotes a rod attached to an attachment member 8 provided in the moving unit 6. As shown in FIG. 2, a near target presentation unit 3 having a near chart 3 a on which a plurality of test targets are drawn is attached to the rod 2 so as to be movable in the longitudinal direction. The near chart 3a can rotate around the axis 3b of the near target presentation unit 3, and a desired target is presented from the presentation window 3c by the rotation. A scale is provided on the rod 2 so that the distance (near distance) from the eye E to be examined located in the examination window 61 to the near chart 3a can be understood. It can be positioned at a desired distance from the optometry E. Further, the attachment member 8 has a configuration in which the attached rod 2 can be folded upward, and when the rod 2 is flipped up to the position shown in FIG. I try not to be. Reference numeral 9 denotes a controller for operating the optometric apparatus main body 1 and the optotype presenting apparatus 20. The controller 9 includes a switch for automatically or manually performing a distance inspection and a near inspection.

  FIG. 3 is a diagram showing the configuration of the controller 9. A liquid crystal display 30 displays optometry information. Reference numeral 31 denotes a switch unit, which includes a target switch group 32, a start switch 33 and a feed switch 34 for program optometry, a far / near switch 35 for switching between a far test mode and a near test mode, a function switch group 36, and the like. Prepare. The function switch group 36 is used when selecting a switch corresponding to various switch displays displayed at a predetermined position below the screen of the display 30. Reference numeral 37 denotes a dial input switch for adjusting the lens power and the like by a dial 38 in a predetermined step. Reference numeral 37a denotes a PD switch for adjusting the position of the examination window 61 to the distance between the pupils of the subject. When the dial switch 38 is rotated after being pressed, the movement of the moving means 40 causes the left and right lens chamber units 60 to move. The interval can be adjusted in predetermined steps. Reference numeral 37b denotes an ADD switch for adjusting the left and right inspection windows 61 to the convergence angle of the subject. When this switch is pressed, the convergence angle of the left and right lens chamber units 60 is adjusted by driving the moving means 40. Such convergence angle adjustment of the lens chamber unit 60 is used in a near-field inspection or a joining inspection for measuring the addition degree of a subject.

  FIG. 4 is a schematic view of the optometry apparatus main body 1 when viewed from the subject side. A plurality of lens disks 64 in which various optical elements 65 (lenses and the like) are arranged (held) on the same circumference are rotatably provided inside the housings of the left and right lens chamber units 60. Further, as shown in the drawing, the lens chamber unit 60 includes a disc cover 62b having a shape in which an inner portion thereof is greatly cut out and a lens chamber body cover 62a. A contact detection mechanism 110 for detecting that the lens chamber unit 60 is in contact with the subject's nose is built in between the disc cover 62b and the lens chamber body cover 62a.

  70 is a forehead abutting against the forehead of the subject, and 71 is a connecting portion for connecting the forehead 70 and the moving unit 6. The forehead support 70 has a role of holding the subject's head and fixing the position of the subject's eye. A forehead detection mechanism that detects that the subject's forehead has come into contact with the forehead pad 70 (the subject's face is located at a predetermined inspection position) via the connecting portion 71 in the moving unit 6. 72 is built-in.

  FIG. 5 is a schematic diagram illustrating the configuration of the forehead detection mechanism 72. A feed screw 73 is inserted through the moving unit 6, and the male screw portion of the feed screw 73 is screwed with the female screw portion of the connecting portion 71. The connecting portion 71 screwed with the feed screw 73 is fitted into the guide hole of the moving unit 6. Reference numeral 74 denotes a spring provided inside the moving unit 6, which urges the connecting portion 71 toward the subject via the feed screw 73. Reference numeral 75 denotes a rotary knob fixed to the end of the lead screw 73 on the examiner side. Since the connecting portion 71 has a groove 77 and the groove 77 and the rotation-preventing pin 76 prevent the connecting portion 71 from rotating, when the examiner rotates the rotary knob 75, the connecting portion 71 is The feed screw 73 moves in the direction of the rotation axis. As a result, the distance (the apex distance) between the corneal apex of the eye to be examined and the examination window 61 is adjusted. Reference numeral 78 denotes an attachment member fixed to the moving unit 6 and having a rotary knob 75 and a fitting portion.

  A light shielding plate 80 is attached to the feed screw 73 via a flange 81. A photo sensor 82 has a role of detecting insertion / removal of the light shielding plate 80. In the forehead detection mechanism 72, when the subject's forehead comes into contact with the forehead pad 70, the connecting portion 71 moves to the examiner side, so that the feed screw 73 screwed with the connecting portion 71 opposes the biasing force of the spring 74. Move to the examiner. Along with this, the light shielding plate 80 moves to the examiner side (the solid line portion in the figure), so the photo sensor 82 detects the light shielding plate 80. When the subject's forehead is away from the forehead pad 70, the light shielding plate 80 is positioned at the dotted line portion in the figure, and the photo sensor 82 does not detect the light shielding plate 80. With such a configuration, it can be detected that the forehead of the subject is in contact with the forehead 70.

  A lamp 85 is attached to the attachment member 78 to notify the examiner that the subject's forehead has contacted the forehead 70. The lamp 85 is turned on when the subject's forehead is separated from the forehead 70 based on an output signal from the forehead detection mechanism 72, and is turned off when the subject's forehead comes into contact with the forehead 70.

  FIG. 6 is a diagram for explaining the slide mechanism and the congestion mechanism of the moving means 40 provided in the moving unit 6. A shaft 42 is fixed to the suspension plate 41 that suspends the lens chamber unit 60, and the shaft 42 is inserted into the hole 43a of the slide base 43, so that the shaft 42 is rotatable for the converging operation. Reference numeral 44 denotes a shaft for driving the suspension plate 41, and the shaft 44 is connected to worms 46 a and 46 b having different directions via a gear 45. An eccentric shaft 51 is attached to the tip of the shaft 44, and the tip portion of the eccentric shaft 51 is engaged with a groove 41 a formed in the hanging plate 41.

  Further, the worms 46 a and 46 b are connected to a driving means including a pulse motor 47, and the worms 46 a and 46 b are rotated by the rotation of the pulse motor 47. By rotating the worms 46a and 46b, the eccentric shaft 51 is rotated via the gear 45 and the shaft 44, and the suspension plate 41 can be converged. On the other hand, the slide table 43 is slidable in the axial direction of the fixed guide 48, and the driving means including a pulse motor 49 for sliding is fixed to a fixed bracket (not shown) together with the fixed guide 48. Screws 50a and 50b having different directions are connected to the pulse motor 49 and engaged with the female screw of the slide table 43. Therefore, by rotating the pulse motor 49, the two slide tables 43 are mutually connected. Move in the opposite direction. By the moving means 40 having such a mechanism, the distance between the left and right lens chamber units 60 (that is, the left and right inspection windows 61) and the convergence can be adjusted.

  FIG. 7 is a schematic cross-sectional view illustrating the main part of the contact detection mechanism 110 that detects that the subject's nose and the left and right lens chamber units 60 are in contact with each other. The upper end of the disc cover 62b has a locking portion 66 having an inverted U-shaped cross section, and is hooked on a locked portion 91 provided on the lens chamber body cover 62a (FIG. 7 ( a)). As a result, the disc cover 62b can be slightly rotated about the rotation axis of the locked portion 91. Note that a gap of about 0.5 mm is formed between the lens chamber body cover 62a and the disk cover 62b body. 7B, the lower end portion of the disc cover 62b has a connecting portion 67 that is connected to the pressing member 93 by a set screw 92. The pressing member 93 connected to the connecting portion 67 includes a small-diameter portion 93a at the middle portion, a large-diameter portion 93b facing the outside, and a large-diameter portion 93c on the apparatus side. The small-diameter portion 93a and the device-side large-diameter portion 93c are connected by a set screw 95. On the other hand, the lens chamber body cover 62 a is provided with a recess 100, and a guide hole 101 is provided at the bottom of the recess 100. The pressing member 93 is fitted in the recess 100 and the guide hole 101 and can move in the axial direction. A spring 96 is interposed in a hollow portion between the concave portion 100 of the lens chamber main body cover 62a and the small diameter portion 93a of the pressing member 93, and the lens chamber main body cover 62a is connected to the lens chamber main body cover 62a via the pressing member 93 in the outward direction. Giving power. A micro switch 111 emits a detection signal when pressed by the pressing member 93.

  Here, when the subject's nose contacts the lens chamber unit 60, a drag is applied to the disc cover 62b. As a result, the disc cover 62b is slightly rotated around the rotation axis of the locked portion 91. Then, on the lower end side of the disc cover 62b, the pressing member 93 connected to the connecting portion 67 moves to the apparatus side against the urging force of the spring 96. By such an action, when the large diameter portion 93 c of the pressing member 93 presses the detection portion of the micro switch 111, a detection signal is emitted from the micro switch 111. According to such a structure, it can detect that the subject's nose and the lens chamber unit 60 contacted.

  The operation of the apparatus having the above configuration will be described based on the control system block diagram shown in FIG. First, when the objective measurement data (spherical power, astigmatism power, astigmatism axis angle) and interpupillary distance are obtained by the objective eye refractive power measurement device 58, the switch unit 31 of the controller 9 is operated, Input the measurement data. Data from the objective eye refractive power measurement device 58 is sent to the microcomputer unit 57 of the optometry apparatus main body 1 and the microcomputer unit 55 of the controller 9 via the relay unit 12. When the interpupillary distance data is input, the microcomputer unit 57 drives and controls the motor 49 based on the input interpupillary distance data, and slides the left and right lens chamber units 60. The interpupillary distance data is input as a command signal for sliding the lens chamber unit 60.

  At this time, if the subject's forehead is in contact with the forehead pad 70, the forehead detection mechanism 72 indicates that the face of the subject is in the inspection position, that is, the nose is between the lens chamber units 60. Detected. When the detection signal from the photo sensor 82 is input, the microcomputer unit 57 prohibits movement in the direction of narrowing the interval between the left and right lens chamber units 60. Thereby, it can avoid that a subject's nose is pinched | interposed into the lens chamber unit 60, and contacts. Further, the microcomputer unit 57 switches the lamp 85 from the on state to the off state. As a result, the examiner can confirm that the subject's forehead is in contact with the forehead pad 70 and the subject's face is at a predetermined examination position.

  Even after the distance between the left and right lens chamber units 60 is adjusted based on the interpupillary distance data of the objective measurement data, when the distance between the pupils of the subject and the distance between the left and right examination windows 61 are different, Furthermore, it is necessary to move the left and right lens chamber units 60 according to the distance between the pupils of the eye to be examined. In this case, the examiner presses the PD switch 37 a of the controller 9 and then rotates the dial 38 to input a command signal for changing the interval between the left and right lens chamber units 60. Also in this case, when there is a detection signal from the photo sensor 82 of the forehead detection mechanism 72, the microcomputer unit 57 prohibits movement in the direction of narrowing the interval between the left and right lens chamber units 60. Accordingly, it is possible to prevent the subject's nose from being sandwiched between the left and right lens chamber units 60 in advance. When there is a detection signal from the photo sensor 82 and a command signal for changing the interval between the lens chamber units 60 is input from the controller 9, the microcomputer unit 55 may pinch the nose to the display 30. And a display indicating that the subject's face is operated away from the device.

  In the moving operation for changing the distance between the left and right lens chamber units 60, when moving the left and right lens chamber units 60 in the direction of increasing the distance, the subject's nose is sandwiched between the lens chamber units 60. Therefore, the microcomputer unit 57 may move the microcomputer as it is without prohibiting the movement.

  Further, when performing the near vision inspection (additional power inspection), as shown in FIG. 2, the near vision target presenting unit 3 is arranged at a predetermined position, and the left and right lenses according to the distance of the near vision chart 3a. The room unit 60 is congested. When the far / near switch 35 is pressed to switch to the near mode or the ADD switch 37b is pressed, a command signal for converging the left and right lens chamber units 60 to a predetermined near distance is input. At this time, the function key 36 can input a near distance (for example, 35 cm, 40 cm, 45 cm, and up to 70 cm) every 5 cm. A command signal for adjusting the convergence angle is input accordingly. Even during this congestion, the left and right lens chamber units 60 are moved in a direction in which the interval is narrowed. In the near examination, the distance between the left and right examination windows 61 is adjusted to the distance between the near pupils (which is narrower than the distance between the far pupils), and further, the convergence operation is performed. The interval of 60 becomes narrower. Therefore, the same control is performed during this congestion operation. That is, even in the congestion operation, when the detection signal is input from the forehead detection mechanism 72, the microcomputer unit 57 prohibits the operation of narrowing the left and right lens chamber units 72. Accordingly, it is possible to prevent the subject's nose from being sandwiched between the left and right lens chamber units 60 in advance.

  In the control as described above, the detection signal from the forehead detection mechanism 72 is used to determine whether or not the subject's nose is positioned between the left and right lens chamber units 60 in a non-contact state. As a means for detecting whether or not the subject's nose is located between the left and right lens chamber units 60, a distance measurement signal from a distance measuring sensor that detects the distance between the subject's face and the optometry apparatus main body 1 is used. May be used. Alternatively, as shown in FIG. 9, a light emitting element 120 is provided on one of the left and right lens chamber units 60, a photo sensor 121 is provided on the other, and a detection signal when the sensor light is blocked by the subject's nose is used. May be.

  If the interval between the left and right lens chamber units 60 is to be narrowed, the examiner instructs the subject's face to move away from the apparatus according to the display 30 and confirms that the lamp 85 is lit. Then, the controller 9 is operated to adjust the interval between the lens chamber units 60. In the operation of widening the interval between the lens chamber units 60, the operation is not prohibited and the drive control is performed as it is. Further, when an operation for narrowing the interval is performed after the interval of the lens chamber unit 60 is once widened, the interval adjusted based on the interpupillary distance data of the objective measurement data can be narrowed first. You may do it.

  In addition, if it is determined by the examiner that the nose is not caught, the function key 36 or the like is prohibited so that the operation of narrowing the interval between the lens chamber units 60 can be performed even if a detection signal from the forehead detection mechanism 72 is received. It is convenient to provide a function for inputting a signal for canceling the operation. That is, normally, in the case of a subject whose distance between the pupils is extremely narrow, a back-eye subject, or a subject whose nose is extremely high, the lens chamber unit 60 may come into contact with the nose. For the subject who can determine that the contact is not sufficient, even if the prohibition operation is canceled, the examination can be performed efficiently without any problem.

  Here, when the control for prohibiting the operation of narrowing the interval between the lens chamber units 60 has been canceled, or when the detection by the forehead detection mechanism 72 is insufficient or an error occurs in the apparatus, The contact detection mechanism 110 shown in FIG. 7 is effective. That is, when the left and right lens chamber units 60 are moved in a narrowing direction in order to adjust the interpupillary distance or to constrict the lens chamber unit 60, the lens chamber unit 60 comes into contact with the subject's nose. The detection signal of the micro switch 111 is output. The microcomputer unit 57 stops driving the pulse motor 47 and the pulse motor 49 of the moving unit 40 when the detection signal of the micro switch 111 is received. More preferably, each motor is instantaneously reversely rotated in a direction in which the interval between the lens chamber units 60 is increased. Thereby, the burden and discomfort to the subject due to the contact between the subject's nose and the lens chamber unit 60 can be reduced. When inspecting such a subject, the inspection may be performed in a state where the forehead support 70 is moved to the subject side until the nose is not in contact with the lens chamber unit 60. In the refractive power test in this state, the distance between the corneal apexes of the lens in the lens chamber unit 60 and the cornea of the eye to be examined changes from the normal distance (for example, 12 mm), but the test was performed based on the change. By performing the process of correcting the refractive power, it is possible to cope with an accurate inspection.

It is the schematic which showed the whole optometry system of this Embodiment. It is the external appearance schematic (at the time of a near examination) which looked at the optometry apparatus of this Embodiment from the examiner side. It is a figure which shows the structure of a controller. It is the schematic of the optometry apparatus main body when it sees from a subject side It is the schematic explaining the structure of a forehead detection mechanism. It is a figure explaining the slide mechanism and the congestion mechanism of the moving means provided in the moving unit. It is a schematic sectional drawing explaining the principal part of the contact detection mechanism which detects that a subject's nose and the lens chamber unit on either side contacted. It is a block diagram of the control system in the whole optometry system of this Embodiment. It is a figure explaining the structure which provided the light emitting element in one of the left and right lens chamber units, and provided the photo sensor in the other.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Optometry apparatus main body 9 Controller 31 Switch part 35 Far / near switch 37a PD switch 37b ADD switch 38 Dial 40 Moving means 57 Microcomputer part 60 Lens chamber unit 61 Inspection window 72 Forehead detection mechanism 110 Contact detection mechanism

Claims (3)

In an optometry apparatus that has a pair of left and right lens chamber units and subjectively examines the refractive power of the eye to be examined by switching and arranging optical elements in the examination window,
Moving means for changing the distance between the left and right lens chamber units, command means for inputting a command signal for driving the moving means, and the face of the subject at a predetermined inspection position with respect to the left and right lens chamber units Detection means for detecting the position and outputting a detection signal; and control means for driving and controlling the moving means based on a command signal from the command means, wherein the detection signal is output from the detection means In some cases, the optometry apparatus includes control means for prohibiting a moving operation for narrowing the interval between the left and right lens chamber units. 2. The optometry apparatus according to claim 1, further comprising release means for canceling control for prohibiting a movement operation in which the control means narrows the interval between the left and right lens chamber units. In an optometry apparatus that has a pair of left and right lens chamber units and subjectively inspects the refractive power of the eye to be examined by switching and arranging optical elements in the examination window,
Moving means for changing the distance between the left and right lens chamber units, command means for inputting a command signal for driving the moving means, and the lens chamber unit is in contact with the subject's nose during the moving operation of the moving means A contact detection means for detecting this and outputting a detection signal; and a control means for driving and controlling the movement means based on a command signal from the command means, and when the detection signal is output from the contact detection means, An optometry apparatus comprising: control means for stopping the movement operation of the movement means or drivingly controlling the movement operation of the movement means in a direction in which the interval between the left and right lens chamber units is widened.