RU151309U1 - EXPERT LIGHT SOURCE LIGHTING UNIT - Google Patents

Abstract

1. A light source for working at the scene of an incident, characterized in that it comprises a housing, on the front side of which there is a translucent screen, a matrix of the main emitters of optical radiation is installed behind the translucent screen, the translucent screen is at least partially covered by an interference filter, a radiator is located on the back of the case, a control panel is located on the bottom of the case, while the manual lighting unit contains a control unit to which m the matrix of the main emitters of optical radiation, and the power unit to which the energy-consuming elements of the unit are connected, connected to the connector mounted on the housing. 2. The light source according to claim 1, characterized in that the matrix of the main emitters of optical radiation is configured to generate optical radiation in the range from 350 to 475 nm. The light source according to claim 1, characterized in that LEDs are used as the main emitters. 4. A light source according to claim 1, characterized in that it further comprises at least one auxiliary emitter of "white" radiation. The light source according to claim 1, characterized in that it contains four auxiliary emitters of "white" radiation located at the corners of the translucent screen. A light source according to claim 1, characterized in that it contains LEDs as an auxiliary emitter of “white” radiation. A light source according to claim 1, characterized in that the control unit is based on a microprocessor. The light source according to claim 1, characterized in that the control unit is configured to

Description

Light source for work at the scene.

The technical solution relates to the field of optical devices, namely to the field of optical radiation sources, and can be used in forensics, in particular, in identifying and preliminary investigation of traces at the scene of an accident.

It is known (US patent 3866858, publ. 1975) a device for aerial photography of the scene containing a balloon, a platform, a radio-controlled camera mounted on the platform, and the balloon is equipped with ropes with anchors.

This device does not provide lighting when photographing the general view of the scene of the incident, as well as the ability to fully examine the scene of the incident, since it is very difficult to move over the scene with the lighting of all points.

Known (RU, patent 2066419, publ. 1996) is a lamp designed to illuminate traffic accidents and containing a base fixed to the base of a flexible post, at the opposite end of which there is a light source, while the post is made of separate components, part of which is made with the possibility of bending, and part in the form of a "spinal" design.

The disadvantage of the known design should be recognized as the impossibility of full coverage of the scene, since the well-known lamp is little adapted to carry.

Known (RU, patent 2286510, publ. 2006) is an inflatable lighting system designed to illuminate the scene of an incident during forensic work, containing an inflatable flexible shell, which is a support for an electric lamp, which is mounted on a support by means of flanges.

A significant disadvantage of the known lighting installation is that when it is folded into the transport position, air is released from the inflatable shell, it loses its hardness and stability and is folded, while its upper part falls to the ground together with the electric lamp. In cases of untrained personnel using the installation, the electric lamp breaks, which significantly reduces the reliability of the lighting installation. Also, during loading, unloading and transportation of the lighting system, both dynamic and random impact loads act on the light bulb, which also leads to damage to the light bulb. It should be noted that the reliability of the installation in extreme conditions associated with the readiness of the lamp for work is very significant.

During the search for patent and scientific and technical literature, no source of information was identified that could be used as the closest analogue of the developed technical solution.

The technical problem solved by the developed device is to expand the assortment of technical means used in forensics when examining the scene of an accident.

The technical result achieved by the implementation of the developed design is to achieve a more complete inspection of the scene of the incident in order to identify material evidence that helps establish the essence of the incident.

To achieve the specified technical result, it is proposed to use a light source to work on the scene of the developed design. It contains a housing with a translucent screen on its front side, a matrix of the main emitters of optical radiation mounted behind the translucent screen, a translucent screen is at least partially covered by an interference filter, a radiator is located on the back of the housing, and a control panel is located on the underside of the housing while the light source for working at the scene of the incident contains a control unit to which is connected a matrix of the main emitters of optical radiation And power supply node to which a source connected to power consuming elements connected to, mounted on the connector housing.

The developed device is characterized in that it contains a matrix of the main emitters of optical radiation, moreover, LEDs capable of generating optical radiation at different wavelengths can be used in the matrix, which makes it possible to choose lighting that is optimal for the wavelength depending on the time of day. The source is made in a manual version, which allows you to place it in space in such a way that illuminate all possible sections of the scene. The presence of a cooling radiator allows the use of sufficiently powerful LEDs that create a bright stream of optical radiation. The use of a translucent screen at least partially covered by an interference filter, preferably interchangeable on one side of the housing, provides a directional beam of optical radiation with the most preferred wavelength. The control unit included in the device allows, if necessary, to regulate the operation of the device.

In various embodiments of the developed device, the matrix of the main emitters of optical radiation is configured to generate optical radiation in the range from 350 to 475 nm.

As the main emitters, LEDs are usually used. However, it is possible to use incandescent lamps in combination with an appropriate filter.

In some embodiments, a hand-held light source for operating at the scene of an incident may further comprise at least one (preferably four) auxiliary emitters of “white” radiation. A set of three LEDs or a halogen lamp can be used as a “white” radiation emitter. Preferably, the emitters of the "white" radiation are located at the corners of the translucent screen, leaving in front of them free of filter space. However, the emitters of the "white" radiation can be located along one side of the translucent screen.

In a preferred embodiment, the control unit may be based on a microprocessor.

In any embodiment, the control unit may be configured to control the radiation power of the main emitters, as well as emitters of "white" radiation.

For ease of use, the device preferably further comprises means for holding the lighting unit in hands. Most often, this tool is a handle attached to the bottom panel of the unit. Usually on this pen place a connector for connecting to an electric current network.

Also, for ease of use, the device may further comprise means for mounting it on a tripod.

In the basic embodiment, the light source for operating on the scene from the front panel contains an interference filter, the main emitters located behind the interference filter, and also auxiliary "white" emitters installed on one side of the translucent screen. On the bottom of the source there is a button for turning it on / off, a button for selecting the type of emitters (main emitters of optical radiation or auxiliary emitters), a button for adjusting the power of the main emitters, an LED indicator of the source's operation, and a connector for connecting the power cable. On the bottom is a handle for transferring the block.

The developed device operates as follows.

You must first wear glasses equipped with an appropriate filter. They turn on the light source for working at the scene using the corresponding button on the bottom panel of the unit, while the auxiliary emitters of "white" light are turned on. It is necessary to darken the room if the work takes place indoors. Turn on using the appropriate button the main emitters of optical radiation. If necessary, regulate the power of the emitters. Inspect the room. At the end of the inspection, turn off the Light Source to work on the scene, remove the glasses and put everything in corf.

Claims (10)

1. A light source for working at the scene of an incident, characterized in that it comprises a housing, on the front side of which there is a translucent screen, a matrix of the main emitters of optical radiation is installed behind the translucent screen, the translucent screen is at least partially covered by an interference filter, a radiator is located on the back of the case, a control panel is located on the bottom of the case, while the manual lighting unit contains a control unit to which m the matrix of the main emitters of optical radiation, and the power unit to which the energy-consuming elements of the unit are connected, connected to the connector mounted on the housing. 2. The light source according to claim 1, characterized in that the matrix of the main emitters of optical radiation is configured to generate optical radiation in the range from 350 to 475 nm. 3. The light source according to claim 1, characterized in that LEDs are used as the main emitters. 4. The light source according to claim 1, characterized in that it further comprises at least one auxiliary emitter of "white" radiation. 5. The light source according to claim 1, characterized in that it contains four auxiliary emitters of "white" radiation located at the corners of the translucent screen. 6. The light source according to claim 1, characterized in that it contains LEDs as an auxiliary emitter of "white" radiation. 7. The light source according to claim 1, characterized in that the control unit is based on a microprocessor. 8. The light source according to claim 1, characterized in that the control unit is configured to control the radiation power of the main emitters. 9. The light source according to claim 1, characterized in that it further comprises means for holding it in hands. 10. The light source according to claim 1, characterized in that it further comprises means for mounting it on a tripod.