RU168968U1 - CAPILLAROSCOPE - Google Patents

Abstract

The claimed utility model relates to the field of medical technology, in particular, to measuring the characteristics of the smallest vessels in the body of capillaries and capillary blood flow. The claimed capillaroscope includes a housing containing a lens with at least one illuminator, a first lens, a second lens, a first photomatrix, a second photomatrix, a dividing optical prism, configured to separate a common light beam into a first light beam and a second light beam . Moreover, a sequentially mounted lens, a dividing optical prism, the first lens, and the first photomatrix are located on the optical axis of the first light beam, and a sequentially mounted dividing optical prism, the second lens, and the second photomatrix are located on the optical axis of the second light beam. Each photomatrix is made with the ability to connect to a computer. EFFECT: obtaining simultaneously two magnifications of the studied surface of an object due to a dividing optical prism and additional optical elements — a second lens and a second photomatrix. 6 c.p. f-ly, 1 il.

Description

The technical field to which the utility model relates.

The utility model relates to the field of medical technology, in particular, to measuring the characteristics of the smallest vessels in the body of capillaries and capillary blood flow.

State of the art

Known capillaroscope (patent RU 132699 U1, published September 27, 2013) containing an optical system with a digital video camera connected to a computer, a lighting system for the study area, a focusing and positioning system, a patient head fixation system, the eye being used as the object of study its microcirculation system, and the lighting system consists of two light sources, one of which allows illumination through the lens, and the other implements side illumination, which allows to obtain high-quality images from the surface of the eye, close to elliptical, while green LEDs are used as light sources to increase contrast. To obtain an image, an optical system with a zoom is used, which allows you to smoothly change the magnification. The disadvantage of this analogue is the lack of constructive ability to simultaneously observe the studied object (capillaries) with different resolutions (for example, with an increase of 200 and 400), since the zoom or zoom lens only increases (or reduces) the image, but does not allow you to simultaneously view the studied image in two increases, which complicates the study and increases the examination time of the patient.

Utility Model Disclosure

The technical result consists in obtaining simultaneously two magnifications of the investigated surface of the object, due to the dividing optical prism and additional optical elements - the second lens and the second photomatrix.

The result is achieved by a capillaroscope including a housing containing a lens with at least one illuminator, a first lens, a second lens, a first photomatrix, a second photomatrix, a dividing optical prism, which is capable of dividing a common light beam into a first light beam and a second light beam moreover, a sequentially mounted lens, a dividing optical prism, a first lens, and a first photomatrix are located on the optical axis of the first light beam, and a sequentially mounted dividing optical prism, the second lens, and the second photomatrix located on the optical axis of the second light beam, wherein each photomatrix is adapted to connect to a computer.

According to a utility model, the illuminator is made of LED.

According to a utility model, the photomatrix is made in the form of a photosensitive matrix.

According to a useful model, the photomatrix is made in the form of a digital-to-analog integrated circuit consisting of photosensitive elements - photodiodes.

According to a utility model, it further comprises a laser pointer configured to illuminate a local location when examining an object.

According to a utility model, the laser pointer is mounted on the same optical axis as the lens.

According to a utility model, the first lens and the first photomatrix are made in the form of a first (for example, digital) video camera, and the second lens and the second photomatrix are made in the form of a second (for example, digital) video camera.

Brief Description of the Drawings

The essence of the utility model is illustrated by a diagram of a preferred embodiment of the claimed capillaroscope.

Utility Model Implementation

The diagram shows a diagram of the inventive capillaroscope, comprising a housing 1, comprising a lens 2 with at least one illuminator 3, a first lens 4, a second lens 5, a first photomatrix 6, a second photomatrix 7, a dividing optical prism 8, configured to share a common the light beam to the first light beam 9 and to the second light beam 10, and a sequentially mounted lens 2, a dividing optical prism 8, the first lens 4, and the first photomatrix 6 are located on the optical axis of the first light beam 9, and the next tionary set separating optical prism 8, and the second lens 5 and the second photomatrix 7 located on the optical axis of the second light beam 10, each photomatrix is configured to connect to the computer 11.

The capillaroscope works as follows.

The surface of the object under study under the lens 2 is illuminated by an LED illuminator 3 and the scattered light from the surface of the object enters through the lens 2 onto a dividing optical prism 8, which, in accordance with the selected magnifications, divides the light beam into the first light beam 9 and the second light beam 10. The first light beam 9 passes through the first lens 4, which focuses the image with magnification, for example, 400 onto the photomatrix 6 (or digital matrix) that transmits the video image to the computer 11. The second (reflected) light The first beam 10 is directed to the second lens 5, which focuses the image with an increase of, for example, 200 onto the photomatrix 7 (or digital matrix) that transmits the video image to the computer 11.

This scheme provides simultaneous observation by the operator of the object of study in two magnifications, greatly facilitating the search for the optimal image and reducing the examination time of the patient, and also significantly reduces the size of the capillaroscope.

It should be noted that in a particular embodiment of the claimed utility model, for compact arrangement of structural optical elements inside the capillaroscope body, one or more rotary mirrors can be additionally installed to direct the first or second light beam to its lens, photomatrix. Also, rotary mirrors can be used additionally to direct the total light beam from the lens to a dividing optical prism. It should be noted that in a private embodiment of the claimed utility model, the capillaroscope further comprises a laser pointer, configured to illuminate a local place when examining an object. The specified laser pointer can be installed in a private embodiment, including behind one of the rotary mirrors, which is made translucent, so that the light beam will be reflected on one side of the translucent mirror, and on the other side of the translucent mirror, a laser pointer will be installed, which along the same optical path in the opposite direction is directed through the optical elements and the lens - to the surface of the object of study.

Claims (7)

1. A capillaroscope comprising a housing comprising a lens with at least one illuminator, a first lens, a second lens, a first photomatrix, a second photomatrix, a dividing optical prism, configured to separate a common light beam into a first light beam and a second light beam moreover, a sequentially mounted lens, a dividing optical prism, a first lens, and a first photomatrix are located on the optical axis of the first light beam, and a sequentially mounted dividing optical prism, second a paradise lens and a second photomatrix are located on the optical axis of the second light beam, and each photomatrix is configured to connect to a computer. 2. The capillaroscope according to claim 1, characterized in that the illuminator is made of LED. 3. The capillaroscope according to claim 1, characterized in that the photomatrix is made in the form of a photosensitive matrix. 4. The capillaroscope according to claim 1, characterized in that the photomatrix is made in the form of a digital-to-analog integrated circuit consisting of photosensitive elements - photodiodes. 5. The capillaroscope according to claim 1, characterized in that it further comprises a laser pointer, configured to illuminate a local place when examining an object. 6. The capillaroscope according to claim 5, characterized in that the laser pointer is mounted on the same optical axis as the lens. 7. The capillaroscope according to claim 1, characterized in that the first lens and the first photomatrix are made in the form of a first video camera, and the second lens and a second photomatrix are made in the form of a second video camera.

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