RU27671U1 - LED FIRING - Google Patents

Description

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the number of LEDs whose optical axis is perpendicular to the specified base.

Achievement of the goal is also facilitated by the fact that a convex-concave mirror reflector with a working surface formed by rotating around a specified longitudinal axis of a part of the parabola having a focal O1 fuzziness coinciding with luminous centers at least parts from the group of LEDs mounted on the upper base of the truncated pyramid.

The technical result is also achieved by the fact that, at least on a part of the working surface of the reflector, perforations are made that pass part of the radiation into the zenith.

The achievement of the result is also facilitated by the fact that the LEDs whose luminous centers are mounted on the focal circle of the ejection of a clave-concave mirrored reflector are selected with a double scattering angle (29.5) at a level of 0.5 of the maximum light intensity equal to the coverage angle (if) part of the parabola forming the working surface of the specified reflector.

The goal is also achieved by the fact that a board with one, two, three or bolt number of LEDs, the otic axes of which are parallel to the longitudinal axis of the fire, is installed on the part of the reflector facing the hatch of the protective cap.

The most preferred embodiments of the device according to the alleged invention are shown in the drawings.

Figure 1 Flashing light, side view, partially in section

Figure 2 The same as in figure 1, section aa

Fig. 3 Flashing light with a convex-concave reflector, view c6oiQf, partially in section

Figure 4 Flashing light with a convex-concave reflector and an additional board with LEDs, side view, partially in section.

Shown in FIG. 1,2,3 and 4 light-signal fire contains a housing 1 made of aluminum alloy or plastic, covered by an optical protective cap 2 assembled in a mandrel 3 through a sealing gasket 4.

The mandrel 3 with the protective cap 2 is fixed and sealed on the housing 1 through the seal 5 with the help of tightening bolts.

The holder of the optical unit (or lamp) with at least one hollow truncated pyramid 7 with an upper base 8 and side facets 9 is mounted with screws using tides inside the tides. Mostly, in the center of each facet 9 of the truncated pyramid, 6 LEDs 10 are mounted (they can be installed two, three or more LEDs), with optical axis OO, perpendicular to the indicated faces 9. On the upper base 8 of the truncated pyramid 7, one, two, three or more LEDs 11, optical axes are additionally mounted OO which are perpendicular to the specified base. When mounting on a holder in two, three or more truncated pyramids, they coincide; with the longitudinal axis of symmetry, the LEDs are installed on their side faces and on the upper base of the upper pyramid (not shown in Fig.). The LEDs 11 mounted on the upper base of the truncated pyramid are selected predominantly with radiation scattering angles (2 s) exceeding the similar scattering angles of LEDs 10 mounted on the side faces of these pyramids. The LEDs 10 and 11 are connected to the electronic converter of the supply network 12. In one embodiment, the light-signal light (see Fig. 3 and 4) on its longitudinal axis bT} is aligned with the truncated pyramid 7 inside the protective cap 2 on the supporting rods-55. 13, a convex-concave mirror reflector 14 is installed with a working surface 15 formed by rotating around a specified longitudinal axis b} a part of a parabola a b having a focal circle FF matching the luminous centers of at least a part of the group of LEDs 11 mounted on the upper base 8 truncated pyramid 7. In this case, the LEDs 11 are located mainly on the annular surface of the upper base 8 so that the focal circle FF passes through their light caves. At least on a part of the working surface 15 of the convex-concave reflector 14, perforations 16 (holes) can be made that allow the part to pass through the zenith (shown by arrows in FIG. 3), thereby ensuring, along with amplification of the 1-beam beam c) scattering paths close to the horizon the output of a part of the radiation at angles close to the zenith (in Fig. 3 is shown by arrows). To increase the yield of fire radiation in angles close to the horizontal, the LEDs 11, the luminous centers of which are mounted on the focal circle FF of the protruding-concave mirrored reflector 14, are selected with a double scattering angle (0 °) at a level of 0.5 of the maximum light intensity equal to the angle of coverage (vP) of the part of the parabola ab forming its working surface 15. In another embodiment of the device (see Fig. 4), radiation is amplified at angles close to the zenith due to the fact that the protective cap 2 is facing the vertex reflector parts are mounted Lebanon board 17 with one, Daum, three or more LEDs 18, preimzshtsestvenpo with a wide beam of radiation scattering. The optical axis 00 of the LEDs 18 is parallel to the longitudinal axis ZZ of the flame. LEDs 11 and 18 parallel or parallel-sequential chains are connected to the electronic Converter of the supply network 19.

The lights work as follows. When power is applied, the LEDs generate light in white, yellow, red, green or blue. The radiation beams partially or completely intersecting and overlapping each other in the space of the formations, the circular indicatrix of the light intensity mainly in the upper hemisphere.

The number of faces of the truncated pyramid 7 is set depending on the selected LEDs (on the scattering angle and the light intensity of the LEDs) to ensure the required level of light intensity and uniform light distribution at given angles of the indicatrix of fire radiation. The number of LEDs installed on the upper base 8 of the pyramid 7 (see figure 1) or on the board 17 (see figure 4) also depends on the scattering of the radiation generated by them and the magnitude of the light intensity to ensure the required uniformity of light distribution of the fire.

Since for a number of applications, for example, for obstruction lights installed on high-rise and extended objects, light distribution in the vertical plane is required with a maximum light intensity at angles of ± 6 ° from the horizon exceeding 2.5 times the maximum radiating to the zenith and the rest of the upper hemisphere, then increasing the efficiency of the fire and improving its lighting parameters is achieved not only through the installation on the upper base of the truncated pyramid of 7 LEDs with a more diffuse scattering angle, but the EP convex-concave mirror of the reflected reflector 14. The radiation of the LEDs 11 reflected from its working surface 15 (shown by arrows in FIGS. 3 and 4) is redistributed in the corners extremely close to the horizon, and part of the radiation transmitted through the hole (perforations 16) in the reflector 14 forms the rest of the fire emission indicatrix in the upper hemisphere.

For other applications, for example, for light marking of aerodromes and heliports, it is advisable to form a fire emission indicatrix in the upper hemisphere of the space by selecting LEDs 11 and 18, respectively (for the variants of lights shown in Figs. 1 and 4) with a wider light distribution.

The implementation of the technical solution according to the invention makes it possible to improve lighting parameters 1.5 to 2 times without increasing the total power of the LEDs, as well as to increase the uniformity of light distribution in the given directions of the upper hemisphere.

Literature:

 1 Certificate for a utility model of the Russian Federation No. 4801,

CL R21d 3/00 Sug 03/05/96 2 RF Patent No. 2153623, cl. F21S 2/00 from 01.20.99g.

Claims (5)

1. A signal light comprising a housing with a protective optically transparent cap and a holder mounted therein with at least one truncated pyramid, with an upper base and side faces on which LEDs are mounted, with optical axes perpendicular to said faces, characterized in that on the upper base of the truncated pyramid, one, two, three or more LEDs are additionally mounted, the optical axes of which are perpendicular to the indicated base.  2. The signal light according to claim 1, characterized in that a convex-concave mirror reflector with a working surface formed by rotating around a specified longitudinal axis of a part of the parabola having a focal circle coinciding with the luminous ones is installed on the longitudinal axis of the fire coaxially with the truncated pyramid at least part of the group of LEDs mounted on the upper base of the truncated pyramid.  3. Light-signal fire according to claims 1 and 2, characterized in that at least part of the working surface of the reflector is made of perforations that transmit part of the radiation to the zenith. 4. Flashing light according to claims 1 to 3, characterized in that the LEDs whose luminous centers are mounted on the focal circumference of a convex-concave mirrored reflector are selected with a double scattering angle (2θ _0.5 ) at a level of 0.5 of the maximum light intensity equal to the angle of coverage (φ) of the part of the parabola forming the working surface of the specified reflector. 5. Light-signal fire according to claims 1, 2, 4, characterized in that a board with one, two, three or more LEDs, the optical axes of which are parallel to the longitudinal axis of the fire, is installed on the part of the reflector facing the top of the protective cap.