SU906508A1 - Refractometer - Google Patents

Description

The invention relates to medical technology, in particular to optical devices for the investigation of clinical refraction of the eye.

A device is known consisting of a set of test glasses and a table with optotypes of one kind or another, placed in a special illuminator at a distance of five meters from the patient. At the same time, the determination of anomalies of the clinical refraction of the eye is made by compensating it according to a certain method until the maximum visual acuity 1 is achieved.

However, the need for preliminary correction of vision to the state of uniformly mixed astigmatism, the presence of a mandatory distance of five meters between the patient and the table with optotypes and special requirements for lighting are significant drawbacks of this device.

Most advanced is a refractometer containing a test object and an optical system 2.

However, the known refractometer does not provide the necessary accuracy for determining clinical refraction due to the discreteness of the optical power of cylindrical and spherical glasses,

It does not allow to measure the amount of accommodation of the astigmatism of the eye, which limits the scope of application of the refractometer.

The purpose of the invention is to improve the accuracy of determining clinical refraction, the amount of accommodation of astigmatism, as well as determining the direction of the main meridians of the astigmatic eye.

The goal is achieved by the fact that in a refractometer containing a test object and an optical system, the optical system consists of a moving optical component and a lens located on the axis of the collimator lens, while the test object is located on the optical axis of the lens in its 20 front focal plane, and moving the optical component is associated with a scale graduated in diopters and located parallel to the optical axis, with the minimum angular size of the test object in the image space of the optical system with Tavlya is from 5 to 20 seconds.

At the same time, in the plane of the test object, a rotating disk with a scale is installed.

The drawing shows an optical diagram of a refractometer, a general view.

The refractometer contains a test-object 1, an optical one consisting of a collimator lens 2 located on the axis, a movable optical component 3 and a lens 4, while the test object 1 is located on the optical axis of the lens 2 in its front focal plane and in the plane Test object 1 is equipped with a swivel disk 5 with a scale (not shown), wherein the ground optical component 3 is associated with the scale b, graduated in diopters and located parallel to the optical axis, with the minimum angular size of the test object 1 in the image space Nij constituting the optical system is from 5 to 20 seconds.

Refractometer is used as follows.

The patient, who examines the test object 1 through the optical system, sets the movable component to 1 component 3 to the maximum: the position close to the test object 1, in which the latter is seen most sharply. With further displacement of the component 3 in the positive direction (i.e., towards the test object 1), the clarity of the picture visible by the patient sharply deteriorates, especially the area located near the center of the test object. When the movable component 3 is displaced from this position in the negative direction (i.e. in the direction from test object 1), the beam sharpness of the test object may not be disturbed, since the change in the power of the optical system is reduced by an increase in eye refraction due to accommodative apparatus. The mandatory condition for the maximum proximity of the movable optical component 3 to the test object is related to the fact that this results in complete deaccomposition of the eye, i.e. the rays forming a sharp image on the retina emanate from a further point of view. If, at the indicated component of component 3, its back focus coincides with the front focus of the ophthalmic lens 4, a parallel beam of rays enters the patient’s eye, which gives a sharp image on the retina. This means that the further point of view is at infinity, i.e. The patient's eye is etho-etropic. This position of the rolling component 3, which corresponds to the emmetropic eye, is taken as the reference point (O diopter),

/ For a myopic eye (myopia), a further point of vision lies at a finite distance, i.e. with the absence of voltage and the voltage of accommodation on the retina, diverging rays are collected. Since the entrance pupil of the patient's eye is combined with the posterior focus of the eye) - lens 4, the distance from the eye to the further point of vision is equal to the distance from the lens to its image ( in this case, it is imaginary), while the clinical refraction of the eye is the reciprocal of the distance to a further point of view and directly proportional to the displacement of the movable component 3.

For the hypermetrical eye, farsightedness) in the absence of accommodation voltage, converging rays are collected on the retina, i.e. the most vigorous viewpoint of such an eye is imaginary and lies behind the retina. In this case, the distance from the eye to a further point of view is equal to the distance from the posterior focus of the ophthalmic lens to its constructed image and the clinical refraction of the hypermetropic eye is directly proportional to the displacement of the moving component 3.

Thus, on a scale b, the clinical refraction of the eye is determined, i.e. type and strength of spectacle for correction of ametropia. To do this, install the movable component 3 in the position as close as possible to the test object 1, at which the patient sees the test object most clearly. When moving mobile component 3 in the negative direction (i.e., in the direction from test object 1), the patient will also see the test object sharply, since physical refraction of the eye will increase due to the voltage of accommodation and compensate for the divergence of the rays created by the device. The limiting position of the movable component 3, which is as close to the eye as possible, at which the eye can still see the test object 1 abruptly, determines the position of the nearest point of view. It can be recorded on a scale of 5 longitudinal movement in diopters.

For an astigmatic eye, it is characteristic that the patient sees the test object differently sharply in all directions. In this case, it is necessary to install the movable component 3 in such a position as close as possible to the test object 1, in which the patient sees rather sharp rays of the test object going in one of the directions. The position of the rolling component 3, measured on a scale of 6 longitudinal displacement (in diopters), characterizes the clinical refraction of the eye in one of its main meridians.

The direction of this meridian is determined as follows.

Claims (2)

Not displacing the movable component 3 install the rotary disk 5 with the scale in such a position where its direction coincides with the direction of the rays seen by the patient most sharply. At the same time, the readout in degrees taken from the circular scale of the disk 5 determines the position of the main merylnan on the astigmatic eye in the TLVO system. Similarly, clinical refraction is determined in the second main channel of the astigmatic eye 1, its direction (it should be perpendicular to the first one). The offered refractormeter is applied; Nen on 20 patients. It was found that the refractometer provides an increase in the accuracy of determining clinical refraction. When determining the ametropia of the eye, the accuracy is 25% higher than the known refractometer and is 0.2 dioprene, when determining the parameters of the astigmatic eye with the proposed refractometer, the accuracy of determining clinical refraction Mary dianes is 0.2 diopters, which is 2.5 times higher than the known refractometer. The proposed refractometer allows measuring the amount of accommodation of the astigmatism of the eye, i.e. diagnose presbyopia, determine its degree and, ultimately, determine the optical power of the spectacle glass. Claim 1. Refractometer containing a test object and an optical system, which is designed to improve the accuracy of determining clinical refraction, the amount of accommodation of astigmatism, the optical system consists of a collimator lens, a movable optical component and a lens located on the axis, The test object is located on the optical axis of the lens in its front focal plane, and the movable optical component is associated with a scale graduated in diopters and parallel to the optical field. s, with the minimum angular size of the test object in the image space of the optical system being from 5 to 20 s. 2, a refractometer according to claim 1, characterized in that, in order to determine the direction of the main meridians of the astigmatic eye, a rotary dial with a scale is installed in the plane of the test object. Sources of information taken into account in the examination 1.Volkov V.V. and other Clinical vis-and refractometry. M., Medicine, 1976, p. 142-150. 2. Authors certificate of the USSR W 121527, cl. A 61 B 3/02, 1959.