JPH0683001U - Visual acuity test equipment - Google Patents

Abstract

(57) [Abstract] [Purpose] A visual acuity test apparatus that guides a target luminous flux to the eye of the subject to perform an optometry, and regardless of the optometry method, the subject always maintains a stable posture with the target luminous flux. To be able to see. A target luminous flux of a target projected on a screen 11 by a target projecting unit 10 of a visual acuity test apparatus main body 1 is reflected by a mirror 30a, and is detected at the mirror 30a together with a detection light from a detection light emitting unit 70. Turned into mirror 3
0b or the like, is sequentially reflected, goes out from the window 40 of the housing 20, and goes out through the subjective eye examination unit 60 to the eye 50 of the subject.
Is guided up to. The control box 80 is provided with a reset button 81 and an up / down button 82,
The examiner uses the reset button 81 and the up / down button 8
2 is used to perform ON control of the detection light and angle control of the mirror 30f. That is, the angle of the mirror 30f is controlled so that the detection light reflected by the mirror 30f comes to the eye 50 of the subject or the vicinity of the face thereof. In this state,
The subject 5 can stably see the target at the height of his / her own eye 50.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a visual acuity test device that guides a target luminous flux to an eye of a subject to examine the eye.

[0002]

[Prior art]

 Various types of visual acuity testing devices have been proposed that allow a subject to view an optotype in a stable posture against changes in the eye height of the subject due to differences in sitting height of the subject. As an example, in Japanese Patent Laid-Open No. 15492/1993, the height when the measurement window of the subjective eye examination unit is adjusted to the eye of the subject is detected, and the angle of the mirror is detected based on the detection result. A visual acuity test apparatus has been disclosed in which the luminous flux of the target is adjusted to be exactly at the eye level of the examinee.

[0003]

[Problems to be solved by the device]

 However, in the visual acuity test apparatus disclosed in the above-mentioned JP-A-5-15492, in order to detect the eye height of the subject, once the subjective eye examination unit is used to detect the eye height of the subject. Need to be adjusted to. Therefore, when performing a visual acuity test without using the subjective eye examination unit, for example, when performing a visual acuity test using only the spectacle test frame, the eye height of the subject cannot be detected. Since it is not possible to adjust the position of the target luminous flux, the visual acuity test will be performed with the target displaced with respect to the eye height of the subject. Therefore, it was difficult for the subject to see the target in a stable posture.

The present invention has been made in view of the above circumstances, and provides a visual acuity test apparatus that allows a subject to always view a target luminous flux in a stable posture regardless of the optometry method. The purpose is to provide.

[0005]

[Means for Solving the Problems]

 In order to solve the above problems, the present invention provides a visual acuity test apparatus that guides a visual target luminous flux to an eye of a subject to perform an optometry, and an optotype projection unit that projects a visual acuity test visual target, and the visual target projection unit. A plurality of reflecting members for guiding the target light flux of the visual acuity test target to the eye of the subject, and the plurality of reflecting members for guiding the target light flux along the optical path of the target light flux. Detecting light emitting means for emitting detection light, and reflecting member driving means for driving at least one of the plurality of reflecting members to adjust the detected light to the position of the eye of the subject or the vicinity of the face of the subject. There is provided a visual acuity test device comprising:

[0006]

[Action]

 The visual acuity test target is projected by the visual target projection means, and the projected target luminous flux of the visual acuity test target is guided to the eye of the subject by the plurality of reflecting members. On the other hand, detection light is emitted from the detection light emitting means, and the detection light is guided to the subject along the optical path of the target light flux by the plurality of reflecting members. When the detected light is not applied to the subject's eye or the vicinity of his / her face, the examiner determines that the target light flux is displaced with respect to the subject's eye height, and drives the reflecting member. A means is used to drive at least one of the plurality of reflecting members, and the detection light is adjusted so as to be emitted to the eye of the subject or the vicinity of the face thereof. When the detection light is emitted to the eye of the subject or the vicinity of the face thereof, the subject can stably see the target at the height of his / her own eye.

[0007]

【Example】

 An embodiment of the present invention will be described below with reference to the drawings. FIG. 2 is an internal structural view of the main body of the visual acuity test apparatus according to the present invention, as viewed from the front. The visual acuity test apparatus main body 1 of the present invention comprises a target projection means 10, a reflection member 30, and a detection light emitting means 70, which are housed in a casing 20 formed in a rectangular parallelepiped shape.

The projector main body 13 of the target projection means 10 irradiates a target, not shown here, with light, and the light is reflected by the mirrors 12 a and 12 b and projected onto the screen 11. The target luminous flux of the target projected on the screen 11 is guided to the mirror 30 a of the reflecting member 30.

The reflecting member 30 is composed of six mirrors 30a, 30b, 30c, 30d, 30e and 30f. Of the six mirrors 30a and the like, the five mirrors 30a to 30e except the final stage mirror 30f are arranged to face each other as shown in the figure with the adjacent mirrors on the optical path of the target luminous flux. ing. The target luminous flux of the target projected on the screen 11 is sequentially reflected by the five mirrors 30a to 30e arranged in this way, and guided to the final stage mirror 30f. The target luminous flux reflected by the mirror 30f provided at the final stage exits from the window 40 provided at the upper front portion of the housing 20 to the outside, and as described later, the eye 50 (see FIG. ) Is guided.

The first mirror 30a is formed as a half mirror and has, for example, a transmittance of 20% (a reflectance of 80%). The detection light emitting means 70 is provided on the side of the mirror 30a opposite to the target light flux reflecting surface. The detection light emitting means 70 emits spot-like detection light, which passes through the mirror 30a and is sequentially reflected by the mirrors 30b to 30f along the optical path of the above-mentioned target light flux to be examined. Is guided to the place.

Next, the overall configuration of the visual acuity test apparatus of the present invention will be described with reference to FIG. FIG. 1 is a diagram showing the overall configuration of the visual acuity test apparatus of the present invention. In the figure, the target light flux of the target projected on the screen 11 by the target projection means 10 of the visual acuity inspection apparatus body 1 is sequentially reflected by the mirrors 30a to 30f, and the target light flux reflected by the mirror 30f is It goes out through a window 40 provided in the upper front part of the housing 20 and is guided to the eye 50 of the subject, and the measurement result is processed by the subjective eye examination unit 60 to perform a predetermined eye examination. Further, the detection light from the detection light emitting means 70, after passing through the mirror 30a, is guided to the eye 50 of the subject by following the same optical path as the above-mentioned target light flux. The final stage mirror 30f is actually arranged as shown in FIG. 2, and the target luminous flux reflected by the mirror 30f is directed toward the front side of the paper surface, but here, in view of the space of the paper surface, It is illustrated so as to face.

When the light guide distance of the optical path between the screen 11 and the mirror 30f is Y and the light guide distance of the optical path between the mirror 30f and the subject's eye 50 is X, the entire light guide is performed at the time of the eye examination. The distance (X + Y) is set to be 5 m.

As shown in the figure, the control box 80 is provided separately from the visual acuity test apparatus body 1. The control box 80 is provided with a reset button 81 and an up / down button 82, and the examiner uses the reset button 81 and the up / down button 82 to perform on-control of detection light and angle control of the mirror 30f. The on control of the detection light and the angle control of the mirror 30f will be described with reference to FIG.

FIG. 3 is a diagram showing an overall configuration for executing ON control of detection light and angle control of the mirror 30f. In the figure, when the examiner presses the reset button 81 of the control box 80, the signal is received by the signal receiving unit 91 on the main body 1 of the visual acuity testing apparatus and sent to the drive circuit 70a via the control unit 90. Upon receiving the signal, the drive circuit 70a energizes the detection light emitting element 70b, and the detection light emitting element 70b emits the detection light by the energization. This detection light is spot-like light, and as described above, is guided to the subject along the optical path of the target luminous flux.

By the way, the mirror 30f, as shown in FIG., The gear 3f ₃ is provided et al are coaxially the gear 3f ₃ is rotated by a pulse motor 3f _2. An origin detecting sensor 3f ₄ is provided adjacent to the gear 3f ₃ . Control unit 90 receives an ON signal of the reset button 81, the driving signals because that based on the detection signal from the origin detection sensor 3 f ₄ resets the mirror 30f to a predetermined origin position circuit 3f Output to ₁ . The drive circuit 3f ₁ receives the signal and drives the pulse motor 3f ₂ , whereby the gear 3f ₃ rotates and the mirror 30f is reset to a predetermined origin position.

On the other hand, when the examiner presses the up / down button 82, the signal is received by the signal receiving section 91 and sent to the drive circuit 3f ₁ via the control section 90. The drive circuit 3 f ₁ receives the signal and drives the pulse motor 3 f ₂ . Thus, to rotate the gear 3 f _3, the angle of the mirror 30f is controlled. For example, when the up button of the up / down button 82 is pressed, the mirror 30f rotates clockwise, and when the down button is pressed, the mirror 30f rotates counterclockwise.

Further, when the control section 90 receives a signal from the up / down button 82, it sends the signal to the drive circuit 70a in the same manner as when the signal from the reset button 81 is received, and the detection light emitting element is sent. The detection light is emitted from 70b.

If the reset button 81 or the up / down button 82 is not pressed within about 5 seconds after the stop of the pulse motor 3f ₂ , the emission of the detection light is stopped by the timer. If either the reset button 81 or the up / down button 82 is pressed again within 5 seconds, the timer is automatically updated and the detection light is continuously emitted. The control box 80 is provided with other various buttons necessary for the visual acuity test, but they are not shown here.

As described above, when the examiner operates the reset button 81 and the up-down button 82 of the control box 80, ON control of the detection light and angle control of the mirror 30f are performed, and the detection light irradiation to the subject is performed. The position is adjusted. The adjustment of the detection light irradiation position will be described with reference to FIG.

FIG. 4 is an explanatory diagram of the detection light irradiation position adjustment. In the figure, when the examiner presses the reset button 81 of the control box 80, the detection light 7 is emitted, and the detection light 7 is reflected by the mirror 30f indicated by the alternate long and short dash line and becomes the detection light 7a, which is the subject 5 Is irradiated. In this case, the detection light 7a deviates above the head of the subject 5 and is irradiated in spots at the deviated position. The examiner can see the spot-shaped detection light 7a and know that the detection light 7a deviates from the subject 5. When the detection light 7a deviates from the subject 5, the target light flux reaching the subject 5 along the same optical path as the detection light 7a also deviates from the subject 5. When the optometry is performed in this state, the subject 5 has to take an unreasonable posture to see the target luminous flux.

Then, the examiner presses the up / down button 82 of the control box 80 to adjust the angle of the mirror 30f. That is, the mirror 30f is controlled to the position shown by the solid line so that the detection light 7b reflected by the mirror 30f is just near the eye 50 of the subject 5 or the face thereof. In this state, the subject 5 can stably see the target at the height of his / her own eye 50.

FIG. 5 is a diagram showing a work procedure when the mirror angle is adjusted. In the figure, the numerical value following S 1 indicates the step number. [S1] First, the subject is seated on the chair. [S2] The examiner presses the reset button 81 of the control box 80. As a result, the mirror 30f is reset to the origin position and the detection light is emitted. [S3] It is determined whether or not the heights of the detected light beam and the eye to be inspected are the same. If they do not match, the process proceeds to step S4, and if they match, the mirror 30f is fixed at that position, and the operation ends. [S4] The examiner operates the up / down button 82 of the control box 80. As a result, the angle of the mirror 30f is controlled and the detection light is emitted. When the angle of the mirror 30f is controlled, step S3 is executed again.

FIG. 6 is a diagram showing a second embodiment of the present invention. The difference from the first embodiment is that the mirror 30e is a half mirror, the detection light emitting means 700 is configured as an LED light emitting device that emits the LED light 7c, and the LED light is reflected near the mirror 30f. This is the point that an auxiliary mirror 30g for doing so is provided. Further, since the LED light 7c is diffused light, a condenser lens 30h is provided between the auxiliary mirror 30g and the detection light emitting means 700.

The mirror 30f and the auxiliary mirror 30g are fixed to the same mount 33 as shown in FIG. At this time, the mounting angles of the mirror 30f and the auxiliary mirror 30g are designed to be slightly different from each other so that both the target luminous flux 300 and the LED light (detection light) 7c reach almost the same position on the subject. It has become. That is, the detection light follows a slightly different path along the optical path of the target luminous flux, but finally reaches almost the same position of the subject, so that the detection light functions as in the first embodiment. Can be achieved accurately.

In the above-described second embodiment, the detection light emitting means 700 is configured as a device that emits LED light, but it may be configured as a device that emits other detection light, for example, laser light. In that case, the condenser lens 30h becomes unnecessary.

Further, although the detection light emitting means 70 and 700 are arranged on the opposite side of the target light flux reflecting surfaces of the mirrors 30a and 30e, the detection light and the target light flux finally reach the subject. It may be placed at another position as long as it reaches almost the same position.

Further, in the above description, the deviation between the target light flux and the height of the eye of the subject is adjusted using the detection light. However, instead of the detection light, a television camera is used for adjustment. It can also be configured. In that case, the television camera is arranged, for example, at the position of the detection light emitting means 70, that is, on the opposite side of the target light flux reflecting surface of the mirror 30a. When a TV camera is placed at this position, the TV camera takes an image of the eye of the subject through the mirror 30a, and the examiner looks at the screen and sees the target luminous flux and the eye height of the subject. You can know the difference between the two.

[0028]

[Effect of device]

 As described above, in the present invention, the luminous flux of the target and the height of the eye of the subject are adjusted by using the detection light, so that the subject stabilizes the target at the height of his or her own eye. You can see it.

Further, the examiner can confirm the deviation between the target light flux and the height of the eye of the subject by the irradiation position of the detection light, and the examiner can adjust the deviation. Further, since the detection light is used, even when the visual acuity test is performed without using the subjective eye examination unit, for example, even when the visual acuity test is performed only with the eyeglass test frame, the target luminous flux and the eye of the subject are not detected. You can adjust the height deviation.

[Brief description of drawings]

FIG. 1 is a diagram showing the overall configuration of a visual acuity test device of the present invention.

FIG. 2 is an internal structural view of the main body of the visual acuity test apparatus according to the present invention.

FIG. 3 is an overall configuration diagram for executing detection light ON control and mirror angle control.

FIG. 4 is an explanatory diagram of detection light irradiation position adjustment.

FIG. 5 is a diagram showing a work procedure when a mirror angle is adjusted.

FIG. 6 is a diagram showing a second embodiment of the present invention.

FIG. 7 is a diagram showing a position of an auxiliary mirror.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 Visual acuity test apparatus main body 3f ₂ Pulse motor 3f ₃ Gear 3f ₄ Origin detection sensor 5 Examinee 10 Target projection means 11 Screen 20 Housing 30 Reflecting members 30a, 30b, 30c, 30d, 30e, 30f Mirror 30g Auxiliary mirror 40 window 50 subject's eye 60 subjective eye examination unit 70,700 detection light emitting means 80 control box (reflecting member driving means) 81 reset button 82 up-down button 90 control section

Claims (2)

[Scope of utility model registration request] 1. A visual acuity test apparatus that guides a visual target light flux to an eye of a subject to perform an optometry, and a visual target projection means for projecting a visual acuity test visual target; A plurality of reflecting members that guide the target light flux of the visual acuity test target to the eye of the subject, and the detection light that is guided along the optical path of the target light flux by the plurality of reflecting members. A detection light emitting unit; and a reflection member driving unit that drives at least one of the plurality of reflection members to adjust the detection light to the position of the eye of the subject or the vicinity of the face of the subject. Characteristic visual acuity testing device. 2. The visual acuity test apparatus according to claim 1, wherein the detection light emitting means emits LED light or laser light as the detection light.