SU1627115A1 - Method of measuring interpupillary distance - Google Patents

Abstract

The invention can be used in ophthalmology. The purpose of the invention is to increase accuracy while simplifying the method. The method, which is carried out using a device containing a ruler 1, located on its jaws 2 and 3 of the plate 4,5 with holes 6 and 7 and eye flaps 8, the screen 10 with a dough in the form of a cross 11, consists in placing the patient in front of the patient the best vision of the patient, the screen 10 with the test so that the horizontal line of the cross 11 is located parallel to its base of the eyes, which allows to increase the accuracy and convenience of measurement. The patient holds the measuring device, observes the test through the eye flaps 8 and the holes 6 and 7 coaxially with them, positions the image centers of the holes 6 and 7 of the plates 4, 5 on the horizontal line of the cross 11 by rocking the sponges 2 and 3 around the normal to the center of the cross 11 of the test, moves The movable sponge 3 along the ruler to coaxially match the images of the holes 6 and 7, controls the position of the coincidence of the centers of the holes and the cross of the dough by closing the eyes one by one. 1 il. -fc fe

Description

The invention relates to medicine, in particular to ophthalmology, and can be used in mass examinations.

The purpose of the invention is to increase accuracy while simplifying the method.

The drawing shows a device for implementing the proposed method.

The method is carried out using a device containing a reading line 1, fixed 2 and movable jaws 3, plates 4 and 5 fixed to them with a circular hole 6 in the first plate 4 and a cross-shaped hole 7 in the second, having a central zone also round of a larger or equal size with the diameter of the hole 6 of the first plate 4. On the plates 4 and 5, eyecups 8 are fixed, coaxially aligned with the holes 6 and 7, A vernier 9 is attached to the movable plate 5, the initial and current divisions of the line 1 coincide with the installation planes of the jaws 2 and 3. In front of the device, place a faucet 10 with a dough in the form of a cross 11 so that its horizontal line is parallel to the base of the patient’s eyes.

The screen 10 is installed at a distance of 25-50 cm from the patient’s eyes, i.e. at the distance of his best vision, perpendicular to the optical axis of the eyes (the direction of the patient’s gaze).

Having installed the screen 10 perpendicular to the optical axis of the patient’s eyes and the horizontal line of the test cross 11 parallel to the base of the patient’s eyes, the latter takes the measuring device by line 1, observes and fixes the center of the cross 11 with both eyes with central vision. The patient sees with peripheral vision images of two holes 6 and 7 of the plates 4, 5, places their centers on the horizontal line of the cross and moves the movable sponge 3 along this line until the image of these holes 6 and 7 coaxially coincides on the center of the cross 11. Placement of images of holes 6 and 7 on the horizontal line of the cross 11 is carried out by shaking the movable and stationary jaws around the normal, mentally drawn to the center of the cross 11. The cross-shaped hole 7 is made larger in diameter than the hole 6 and overlaps it. therefore, the centers of holes 6 and 7 can be combined more easily and more accurately. The position of alignment of the centers of the holes 6 and 7 with the center of the cross of the test 11 is controlled by closing the eyes one by one, if the centers of each visible hole and the cross of the test 11 coincide, then they take a nonius line of 1 with an accuracy of 0.1 mm.

PRI me R 1, Patient T., 52, taking the device by the measuring line, put the eyecups of the device to her eyes and. looking at the test object, made in the form of a cross, drawn with ink on a sheet of paper, moved the screen with eyecups mounted on the movable element of the device, until the hole of the fixed screen and the movable screen made in the form of a cross, the central zone of which is made in the form of a circle larger or equal diameter. Shaking the measuring device around the nose bridge and around the center of the cross of the test object, she displaced the hole of the screen of the fixed sponge relative to the cross-shaped hole of the moving frame symmetrically to the horizontal axis of the cross, making sure the axisymmetric coincidence of the hole. Closing her eyes one by one, she was convinced of the coincidence of the centers of the holes and the cross of the test object. Having removed the measuring device, I handed it to the doctor. The doctor on the initial stroke of the moving frame (nonius) took an integer count, and on the matching strokes - a fractional number, it is 56.7 mm. The patient repeated the measurements twice: 56.9 and 57.2 mm. The arithmetic mean value is 57.0 mm.

PRI me R 2. Patient K., 42, carried out measurements of the interpupillary distance to read close by the method described above. 61.2, 62.0 and 61.4 mm were obtained. The base of the eyes was 61.5 mm.

Sample Patient M.A., 43. She measured the base of the eyes for the distance, observing a point source of light, and she aligned peripheral vision with the holes of the screens of the measuring device. Data of 66.5, 67.0 and 66.9 mm were obtained. The average eye base is 66.8 mm.

Using the method of measuring the interpupillary distance of the eyes in comparison with the prototype allows to increase the accuracy and convenience of measurement due to the fact that they install a screen with a test in the form of a cross perpendicular to the patient’s eye in front of the best vision, this allows you to orient the images of the holes in the plates of the device, to combine in a specific location and gives the opportunity to control; the horizontal line of the test cross is set parallel to the base of the patient’s eyes, as this is the shortest distance to the base of the eyes.

Due to the fact that the patient himself holds the measuring device, made in the form of a measuring ruler 5, on the reading lips of which plates with holes of various sizes and shapes and with eye cups coaxial with them are fixed, and he observes the test through the eye cups with holes of various sizes and shapes in plates, observation in the hole through the eyecups gives less interference and the combination of images of the holes the patient himself can combine more accurately. ^ 5

Due to the fact that the patient places the image of the centers of the holes in the plates of the measuring device on the horizontal line of the cross of the test by swaying the moving and stationary jaws of the measuring device around the normal to the center of the cross of the test, this allows the plates to be moved by the shortest distance until the images of the centers of the holes coincide with the center of the cross of the test.

By moving the movable jaw of the measuring device, the patient monitors the position of coincidence of the centers of the holes and the cross of the test by alternately closing the eyes β βθ. This action can be used to control the exact alignment of the images of the centers of the holes of the plates. In addition, the proposed method saves the doctor’s time, increases its productivity, is accessible to junior and secondary medical personnel, the method is time-saving, simple, easy to use and can be widely used in clinics, hospitals, and specialized ophthalmological centers.

Claims (1)

Claim The method of measuring the distance between the pupils of the eye by presenting the test subject with paired test objects spaced in front of each eye spaced in front of each eye, and determining the distance between the pupils according to the coincidence of test objects in each pair, installed with the possibility of moving relative to each other, characterized in that In order to improve accuracy while simplifying the method, the near test objects in each pair are different in configuration, and as a second test object they represent a cross, a mouth tained at a distance of best vision.