RU220676U1 - Shadowless LED illuminator - Google Patents

Abstract

The utility model relates to the field of lighting engineering, in particular to LED illuminators capable of producing a shadow-free effect due to several light sources located around the optical axes of each user's eye. The device can be used in all types of activities where it is necessary to provide shadow-free lighting, which is characterized by the absence of shadows, glare and reflections. The shadowless LED illuminator contains several light sources located along the perimeter of the frame rims. The design is attached to glasses with corrective or zero lenses using a clothespin. LEDs located around the optical axes of each user's eye form a complex light flux directed at the illuminated object. Due to the mutually opposite arrangement of light sources relative to one optical axis, a shadowless effect occurs. Two light streams from the left and right rims of the frame, directed along the corresponding optical axes, form stereoscopic vision and provide shadow-free illumination of the working field, which improves the quality of perception of the shape and detail of objects.

Description

Shadowless LED illuminator refers to the field of lighting technology, in particular to LED illuminators capable of producing a shadowless effect due to several light sources. The device can be used in all types of activities where it is necessary to provide shadow-free lighting. In areas such as electronic equipment repair, jewelry making, biology, archeology, forensics, the shadowless illuminator is in greatest demand.

A shadowless cold light illuminator for stereomicroscopes is known [Patent RU2252441C1 according to IPC G02B 21/06. – Publ. 05/20/2005 Bulletin. No. 14], containing a ring with lighting elements mounted on the lens of a stereomicroscope, and a power source. The lighting elements are mounted on rods installed in the ring sockets on spherical hinges with the possibility of longitudinal movement in them. High-brightness LEDs are used as lighting elements.

The known invention is applicable only in conjunction with complex optical equipment, in contrast to the proposed device, which is a personal lighting instrument and can be used in conjunction with ordinary glasses.

The objective of the proposed utility model is to achieve a shadow-free effect when objects are artificially illuminated. The shadowless effect is characterized by the absence of shadows, highlights and reflections and provides a holistic perception of all the details in question. Using an adaptive light will improve comfort when working in low light conditions.

The technical result is achieved by the fact that the utility model contains several LED light sources 1 located along the perimeter of the rims 3. To achieve a shadow-free effect, the line connecting the LEDs on each rim must form a closed contour surrounding the optical axis of the eye. The structure is attached to glasses with corrective or zero lenses using a clothespin 4 located on the bridge. To form the optimal directional pattern of the light source, each LED is equipped with a reflector 2 (Fig. 1).

The shadowless effect occurs when there are several light sources located either around the illuminated object or around the optical axis of the image perception organ. The result is light that is characterized by uniform, intense, diffuse illumination of the object. The LEDs of the device 6, located around the optical axes of each eye 5, form a complex light flux directed at the illuminated object 7. Due to the mutually opposite arrangement of light sources relative to one optical axis, a shadowless effect 8 occurs. Increasing the number of LEDs helps to achieve the best result (Fig. 2 ). Two light streams from the left and right parts of the frame, directed along the corresponding optical axes, form stereoscopic vision and provide shadow-free illumination of the working field.

The functional elements of the proposed utility model are shown in the diagram of an LED shadowless illuminator (Fig. 1). The scheme for the formation of a shadowless effect due to the location of light sources around the optical axes of each eye is illustrated in Fig. 2.

The efficiency of the utility model is achieved by optimizing the design for the use of a shadowless illuminator in everyday life. Due to its low cost, the device can be available to a wide range of users.

Claims (1)

A shadowless LED illuminator containing a hollow frame consisting of two rims and a bridge with a clothespin, LEDs equipped with reflectors, characterized in that the LEDs are evenly located along the perimeter of the rims, and the line connecting the LEDs on each rim forms a closed loop surrounding the optical axis of the eye .