RU167813U1 - MEDICAL OPERATING LIGHT - Google Patents

Abstract

The utility model relates to lighting equipment and relates to a medical operating lamp. The lamp includes a laser source, an element of fluorescent material, a system for generating rays incident on an element of fluorescent material, a main mirror and a system for generating rays from fluorescent material on the main mirror. The system for generating rays from the fluorescent material to the main mirror includes a tablet of fluorescent material and a mirror mounted on the back surface of the tablet. The main mirror is made in the form of a thin-walled element of complex geometric shape, providing a smooth transition of illumination inside the light spot from the center to its periphery with a ratio of the spot diameter of 50% light to the spot diameter of 10% light not less than 0.5. The technical result consists in increasing the intensity and uniformity of the light flux. 2 s.p. f-ly; 1 ill.

Description

The utility model relates to lighting equipment, namely to lamps, in particular, to medical operating lamps.

A known lighting system (US Pat. RF No. 2480801, s. 16.12.2008, IPC G02F 1/13357) containing a light source, a scattering element and a mirror rear reflector, and the light source is configured to emit light to the mirror rear reflector reflecting, according to at least a portion of the light emitted by the light source to illuminate the scattering element, wherein the shape of the mirror rear reflector generates a substantially uniform distribution of the light flux incident on the scattering element to the scattering element, in which The second element contains a first edge near the light source and a second edge far from the light source, the first edge and the second edge defining an imaginary flat surface having a normal axis, and the axis of symmetry of the light source defines an additional angle (β) with a normal axis, and an additional angle ( β) is in the range of plus or minus 30 °.

The well-known lighting system provides high uniformity and uniformity of the light flux in all directions, which is necessary for general lighting fixtures, while medical fixtures should have a high directivity and concentration of the light flux, so as to provide not general, but local illumination.

A well-known BMW laser headlight (Translation of an article from http://wot.motortrend.com.), Containing laser sources, mirrors, directing laser beams onto an element of fluorescent material, an element of fluorescent material, a lens that forms and directs the light beam on a mirror and a mirror forming a luminous flux illuminating the road.

The known device cannot be used as a medical lamp, because headlight design is provided for the formation of a horizontal beam stream.

The objective of the proposed technical solution is to develop a medical operating lamp with an intense uniform luminous flux at a low level of heat dissipation, which reduces the size and power consumption of the lamp.

This problem is solved due to the fact that in a medical operating lamp containing a laser source, an element of fluorescent material, a system for generating rays incident on an element of fluorescent material, a primary mirror, a system for generating rays from fluorescent material on a primary mirror,

an element of fluorescent material, the front light-emitting surface of which is located in a plane perpendicular to the axis of the main mirror and parallel to the rear (supporting) surface,

the system of forming rays from the fluorescent material to the main mirror is made in the form of a tablet of fluorescent material, two faces of which are parallel, one of the faces is located in a plane perpendicular to the axis of the main mirror and an additionally installed additional (rear) mirror, designed to reflect the rays from the back (reference ) the surface of the element is made of fluorescent material, for rays to hit the surface of the main mirror,

the main mirror is made in the form of a thin-walled element of complex geometric shape, the coverage angle of which is 180 degrees, which ensures that all the rays from the fluorescent material hit the surface of the main mirror and is designed to form a light flux that provides a smooth transition of illumination inside the light spot from the center to its periphery with the ratio of the spot diameter of 50% illumination to the diameter of the spot of 10% illumination not less than 0.5;

an element of fluorescent material has a high color rendering index corresponding to 85≤R _a ≤100;

the light-emitting surface of an element of fluorescent material lies in a plane perpendicular to the axis of the main mirror.

The surface shape of the main mirror 3 is selected individually, depending on the operating conditions of the product and the required working field:

- during abdominal operations, the depth of illumination should be maximum, while the size of the light spot can be quite small;

- for a medical operating lamp, it is necessary to ensure that the patient's eyes are not exposed to light, while the profile of the light spot will have an elliptical appearance.

The tablet of the phosphor mixture 4 is always installed in the focus of the main mirror 3, in particular, on the axis 7 of the main light flux 6, and the front light-emitting surface (onto which a parallel beam of laser radiation falls) is located in a plane perpendicular to the axis of the main mirror. This arrangement of the tablet of the phosphor mixture 4 simplifies the optical lighting system and reduces its dimensions.

An element of fluorescent material consists of a mixture of phosphors, the front light-emitting surface (onto which a parallel beam of laser light source falls) is located in a plane perpendicular to the axis of the main mirror and the rear (reference) surface of which is parallel, which ensures that all the rays from the element hit the main mirror .

In addition, the placement of the light-emitting area of the tablet of the phosphor mixture 4, the rear (supporting) surface, which is parallel to the front light-emitting surface, on the mirror surface of the additional mirror 5 increases the luminous flux by reducing the absorption of luminescent light by the supporting element.

The location of the light-emitting surface of the element of fluorescent material in a plane perpendicular to the axis of the main mirror, with an angle of coverage of the main mirror of 180 degrees, ensures that all the rays from the element from the mixture of phosphors reach all the main mirror, which increases the intensity of the light flux.

The presence of an additional mirror 5, located behind the supporting surface of the tablet made of fluorescent material, allows the fullest use of the light energy produced by the element from the fluorescent material due to the reflection of rays from the back (supporting) surface of the element made of fluorescent material onto the surface of the main mirror, and to form a highly concentrated luminous flux meeting the requirements for operating and dental fixtures.

The figure shows a medical operating lamp with a laser source.

Medical surgery light includes:

1 - laser diode, 2 - collimator, 3 - primary mirror, 4 - tablet of a phosphor mixture, 5 - additional (rear) mirror.

Position 6 shows the path of the rays reflected from the main mirror 3, position 7 corresponds to the axis of the main light flux.

The laser radiation source is a semiconductor laser diode 1 blue, violet or ultraviolet range.

The monochromatic light emitted by the laser diode 1, incident on a tablet from a mixture of phosphors 4, is converted into white light with a high conversion coefficient (more than 0.95). A selection of various combinations of the composition of the phosphor mixture creates light radiation with spectral characteristics close to the spectrum of reference light sources.

The luminous flux of the laser diode 1, passing through the collimator 2, is sent to the tablet 4 of the phosphor mixture, where it is converted into white light. The luminous flux from the tablet 4 of the phosphor mixture formed on the rear (supporting) surface of the tablet, which did not hit the surface of the main mirror, with the help of an additional mirror 5, enters the main mirror 3. Then, the white stream of light from the main mirror 3 is directed to the illuminated object.

The use of the claimed medical operating lamp allows you to provide intensive uniform light output at a low level of heat dissipation, which reduces the size and power consumption of the lamp.

Claims (6)

1. Medical operating lamp containing a laser source, an element of fluorescent material, a system for generating rays incident on an element of fluorescent material, a primary mirror, a system for generating rays from a fluorescent material on a primary mirror, characterized in that the element is of a fluorescent material, the front light-emitting surface of which is located in a plane perpendicular to the axis of the main mirror and parallel to the rear (supporting) surface, the system of forming rays from the fluorescent material to the main mirror is made in the form of a tablet of fluorescent material, two faces of which are parallel, one of the faces is located in a plane perpendicular to the axis of the main mirror and an additionally installed additional (rear) mirror, designed to reflect the rays from the back (reference ) the surface of the element is made of fluorescent material, for rays to hit the surface of the main mirror, the main mirror is made in the form of a thin-walled element of complex geometric shape, designed to form a luminous flux that provides a smooth transition of illumination inside the light spot from the center to its periphery with a ratio of spot diameter of 50% light to spot diameter of 10% light not less than 0 ,5. 2. The medical operating lamp according to claim 1, characterized in that the fluorescent material element has a high color rendering index corresponding to 85≤R _a ≤100. 3. Medical operating lamp according to claim 1, characterized in that the light-emitting surface of the element of fluorescent material lies in a plane perpendicular to the axis of the main mirror.

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