RU2153623C1 - Circling guidance signal light - Google Patents

Abstract

FIELD: spatial light signaling primarily to upper hemisphere. SUBSTANCE: device used as obstruction light and built around light-emitting diodes has case with protective cap that accommodates holder in the form of fitting mounting two, three, or more hollow regular truncated pyramids whose longitudinal symmetry axes are aligned; their side faces carry on their apothems light-emitting diodes with optical axes perpendicular to mentioned faces of truncated pyramids. Each of side faces of mentioned pyramids is perpendicular to axis crossing single optical center on longitudinal symmetry axis of light and emitting center of light-emitting diode mounted on this face. One design version of device has its bottom hollow regular truncated pyramid joined through its lower base with annular convex mirror-reflection member shaped as parabola, that is, made in the form of part of paraboloid whose focal circumference is aligned with emitting centers of light- emitting diodes. EFFECT: improved lighting and thermal characteristics, simplified design. 7 cl, 5 dwg

Description

 The present invention relates to lighting engineering, in particular to circular signal lights with a spatial light signaling mainly in the upper hemisphere, for example to obstruction light signal lights, based on semiconductor light emitting diodes. Obstruction light signals are intended for spatial signaling, light marking as a part of aerodrome and heliport light signal complexes or light barriers for high-altitude and extended obstacles, which can worsen the safety conditions for flying aircraft and helicopters at night and in daytime in conditions of poor visibility.

 The lights are installed on tall and long buildings, industrial pipes, masts, pylons of power lines, etc. Red, amber or green light signals can be used for marking helipads and taxiways of airfields, as navigation signs for waterways, and also as signal lights for special vehicles operating in pulsed mode as well.

 Known light-signal device for circular viewing [1], comprising a housing with a cylindrical Fresnel lens mounted on it, inside which a plastic stand is mounted in the form of a direct extended octagonal prism (octahedron) with light-emitting diodes assembled on lateral faces around the circumference.

The disadvantages of the device are due to the relatively low light intensity and a narrow radiation pattern in the vertical plane, providing scattering angles of not more than 90 ^o .

 As a prototype, a light-signal light [2] was selected, comprising a housing with a combined protective glass, a lid and a cylindrical Fresnel lens mounted on it, inside of which two, three or more groups of light-emitting diodes with radially oriented optical axes assembled on racks of the cylindrical ring holder.

 The disadvantages of the prototype are associated with poor lighting parameters of the device due to the fact that the Fresnel lens does not provide a wide light distribution of fire in the vertical plane (there is no radiation at the zenith), which makes it impossible to observe it at all angles above the horizon. In addition, the design of the device is complicated due to the use of a Fresnel lens and a combined protective glass with a cover.

 The aim of the invention is to improve lighting and thermophysical characteristics while simplifying the design of light-signal fire.

 This goal is achieved by the fact that in the circular signal light of fire, comprising a housing with a protective cap and two, three or more groups of light-emitting diodes mounted on the holder connected to current supply means, said holder is made in the form of fittings with two assembled on it three or more hollow, correctly truncated pyramids with a coinciding longitudinal axis of symmetry, on the apofem of each of the side faces of which light-emitting diodes with optical axes are mounted, perpendi ulyarnymi said faces of the truncated pyramid.

 This goal is achieved by the fact that each of the side faces of hollow, correctly truncated pyramids is perpendicular to the axis passing through the single optical center located on the longitudinal axis of symmetry of the fire and the radiating center of the light-emitting diode installed on it. The technical result is also achieved by the fact that hollow, correctly truncated pyramids are mounted on the armature of the holder coaxially within the angle at the top of the lower pyramid and the side faces of each of them form channels between themselves for the passage of heated air.

The achievement of the task is also facilitated by the fact that the apofems of each of the side faces with light emitting diodes mounted on them, at least one of the hollow truncated pyramids, are displaced around the limit axis of symmetry of the fire in a plane perpendicular to the specified axis relative to the apofems of each of the side faces of the other hollow truncated pyramids within a half angle of 360 ^o / n, where n is the number of faces of the lower hollow truncated pyramid.

 The technical result is achieved by the fact that the lower hollow correctly truncated pyramid of the holder reinforcement for a group of light-emitting fire diodes is coupled by the lower base with an annular, mirror-reflecting concave element having a parabola profile, the focal circle of which coincides with the radiating centers of these diodes.

 The achievement of the result is also facilitated by the fact that the outer surface of the side faces of each hollow, correctly truncated pyramid is covered with a layer of mirror-reflecting radiation, for example, aluminum.

 The goal is also achieved by the fact that the hollow, properly truncated pyramid is made in the form of a curly shell mounted and curved on the edges of the truncated pyramid of the holder reinforcement.

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

 FIG. 1 - side-light flashing light, side view, partially in section.

 FIG. 2 is the same as in FIG. 1, top view, section A - A.

 FIG. 3 - flashing light of a circular view with a ring element mirror-reflecting radiation, side view, partially in section.

 FIG. 4 - the same as in fig. 3, top view.

 FIG. 5 is an optical diagram of a signal light (ray path in a vertical plane).

 Shown in FIG. 1, 2, 3, and 4, the round-view flashing light comprises a housing 1 made of aluminum alloy or suitable plastic, covered optically transparent in a selected region of the spectrum, for example, in the visible spectral range, by a protective cap 2 mounted in the mandrel 3 through a sealing gasket 4 and retained on the mandrel of the annular element 5.

 The mandrel 3 with a protective cap 2 and an annular element 5 is installed, fixed and sealed on the housing 1 through the seal 6 using a hinge and tightening bolts.

образной скобы, на которой установлены две (фиг. 1), три (фиг. 3) или большее количество съемных полых, правильно усеченных пирамид 10 и 11 с совпадающей продольной осью симметрии, в частности для первого варианта (фиг. 1) выполненных в виде съемного полого, правильно усеченного восьмиугольника пирамида 10 (нижняя пирамида) и съемного полого, правильно усеченного тетраэдра 11 (верхняя пирамида).Inside the protective cap 2 on the ring element 5, the reinforcement of the removable holder 7 is assembled, on which two (Fig. 1) three (Fig. 3) or more groups of light-emitting diodes are mounted, for example two groups of diodes 8 and 9. The holder 7 is made in the form

a shaped bracket on which two (Fig. 1), three (Fig. 3) or more removable hollow, correctly truncated pyramids 10 and 11 with a matching longitudinal axis of symmetry are installed, in particular for the first variant (Fig. 1) made in the form removable hollow, properly truncated octagon pyramid 10 (lower pyramid) and removable hollow, correctly truncated octagon tetrahedron 11 (upper pyramid).

 On the apophem “ab” of each of the side faces of the truncated pyramids 10 and 11 are mounted mainly one at a time (but two, three or more can be installed) of the light emitting diode 8 and 9, respectively, whose optical axis F'O 'is perpendicular to the said side faces of the truncated pyramids. Each of these faces, in turn, is perpendicular to axis 00 (see Fig. 5), passing through a single optical center O located on the longitudinal axis of symmetry ZZ 'of fire and the emitting center F', F '' or F '' 'of the light emitting diode.

 The upper truncated pyramid 11 can be installed on a stand-alone fixture of the removable holder 12, ensuring the replacement of a group of failed light-emitting diodes 9 during operation, regardless of the group of diodes 8 installed on an adjacent truncated pyramid 10.

 Hollow, correctly truncated pyramids 10 and 11 with light-emitting diodes are installed in repeating their shape along the perimeter of the nests of the curly flanges 13 and 14 of the holders 7 and 12, respectively, and are mechanically fixed by spring latches 15 and 16.

 The upper hollow, correctly truncated pyramid 11 can be installed and secured with ribs directly on the faces of the lower truncated pyramid 10 (not shown in Fig.).

Hollow, correctly truncated pyramids 10 and 11 with light-emitting diodes are mounted on the armature of the holder coaxially within the angle φ _o at the top of the lower pyramid (shown by the dashed line in Fig. 1) and the side faces of each of them are oriented to the longitudinal axis of symmetry of the fire ZZ '(Fig. 1) at an angle φ _1/2 greater than the angle of inclination φ _{o / 2 of the} side faces of the lower truncated pyramid 11. In this case, the side faces of the hollow, correctly truncated pyramids 10 and 11 form channels 17 for the passage of heated air, i.e. to enhance convective heat transfer during the operation of the fire.

Apofemy 'ab' of each of the side faces, with light emitting diodes 8 and 9 (see Fig. And 2) or 18, 19 and 20 (see Fig. 3 and 4) installed on them, at least one of the hollow truncated pyramids , for example 21, are displaced around the longitudinal axis of symmetry of the fire ZZ 'in a plane perpendicular to the specified axis (in the horizontal plane) relative to the apofem of each of the side faces of the other hollow truncated pyramid 22 and / or 23 within a half angle of 360 ^o / n, where n is the number of faces of the lower hollow, correctly truncated pyramid.

In particular, in the fire shown in FIG. 3 and 4, the apothems of the lateral faces of the hollow octagonal truncated pyramid 22 are offset relative to the apothem of the similar lower pyramid 23 by an angle of 20 ^o .

When using light emitting diodes with a wide conical beam of radiation scattering of ≈ 60-120 ^o in the fire design, the lower hollow, correctly truncated pyramid 23 (see Figs. 3 and 4) of the holder of the holder of these diodes 18 is advisable to pair the lower base with an annular, mirror-reflecting radiation by a concave element 24 having a profile of a part of the parabola 25 (see Fig. 5), i.e. forming a paraboloidal ring, the focal circle of which coincides with the luminous centers F 'of these light-emitting diodes 18 (indicated in Fig. 3 by the + sign). The arrows in all the drawings show the rays emanating from the luminous centers of the light emitting diodes, the reflected rays from the ring element 24.

 Hollow, correctly truncated pyramids 10 and 11 (Fig. 1) and 21, 22, 23 (Fig. 3) of the reinforcement of the holders are made mainly of heat-conducting material, for example, aluminum or its alloys.

 This also makes it possible to give them the functions of cooling radiators, which ensure effective conductive and convective heat exchange with the environment, which is important for cooling powerful semiconductor light-emitting diodes.

 It is allowed to manufacture hollow truncated pyramids also from heat-resistant plastic, including fiberglass.

 Hollow, correctly truncated pyramids can be made in the form of a figured shell, with mechanically fixed ends 26 (see Fig. 4), mounted and curved on the edges of the truncated pyramid 23 of the holder reinforcement. In both cases, the outer surface of the side faces of each hollow, properly truncated pyramid is covered with a mirror-reflecting layer, for example, aluminum, reflecting the scattered radiation coming from the walls of the protective cap 2.

 Both versions of the device provide for electric series-parallel connection of chains (4 light-emitting diodes for the variant shown in Fig. 1 and 2, and 6 diodes for the variant shown in Fig. 3 and 4) by the method of printed circuit mounting on flexible foil fiberglass panels (not shown) with connecting them to the current lead 27 to the Converter 28 of the supply network.

As light-emitting diodes 8 and 9, high-power diodes of the HPWL-VD01 series of HEWLETT PACKARD company with a scattering angle of 2θ _0.5 = 120 ^o with lobe current leads or high-power diodes of the type U-266B OPTEL LLC (Russia) with wire can be used conclusions. In all cases, current leads are insulated on the truncated pyramids with heat-resistant wires with a fluoroplastic sheath and connected to curved printed circuit boards.

 The proposed light-signal lights are connected to an industrial AC network 220 V, 50-60 Hz or to a DC source with a voltage of 12-48 V.

The lights work as follows. When power is applied, light-emitting diodes generate light beams, mainly of a conical configuration, which intersect (see Fig. 5) mainly on the “tails” of the light distribution curve of each diode or overlap with it, filling the upper hemisphere with radiation (the course of the rays is shown by arrows). When using the proposed circular viewing lights as obstruction lights, the light distribution curve of the lights is formed with high uniformity ranging from zenith to 5 ^o , below the horizon with a light intensity of at least 10 cd.

The use of an annular, mirror-reflecting radiation of a parabolic element 24 (Fig. 3 and 4) or 25 (Fig. 5) allows you to redistribute (shown by arrows) a part of the light flux from the lower hemisphere to the zone from 4 to 15 above the horizon, thus increasing the light intensity in the indicated angles when using the previously mentioned light emitting diodes up to 12-15 cd,
Mounting high-power light-emitting diodes 8 and 9 (Fig. 1 and 2) or 18, 19 and 20 (Fig. 3 and 4) in thermal contact with the flat faces of hollow, correctly truncated pyramids 10, 11 and 21, 22, 23, respectively, provides a high heat removal and heat dissipation on the walls of these pyramids made of heat-conducting material.

 The location of the truncated pyramids with the formation of channels 17 between their side faces enhances the cooling efficiency due to convective heat transfer.

 Thus, the lighting characteristics of light-signaling lights are improved due to the fixed and correctly distributed spatial orientation of the optical axes of the light-emitting diodes in the upper hemisphere, as well as the result of the use of a ring, mirror reflective element and mirrored outer faces of truncated pyramids.

 The thermophysical parameters of the lights are improved due to more efficient heat removal of heat sources and light-emitting diodes in thermal contact with the fixtures of the holders and heat dissipation into the environment.

 Along with this, the design of the fire is simplified as a result of the use of hollow, correctly truncated pyramids as a fixture for holders of light-emitting diodes and a simpler protective cap that provide the required spatial light distribution of the fire in the upper hemisphere.

Literature
1. L. Kogan. Further development of optoelectronic devices. Appendix to the journal "EC""NewComponents", N 4 (7), 1998

 2. US patent N 5224773, CL. F 21 V 5/02, nat. class 362-227, publ. 07/06/93

Claims (7)

 1. A signal light of circular visibility, comprising a housing with a protective cap and two, three or more groups of light-emitting diodes mounted on the holder connected to current-carrying means, characterized in that the holder is made in the form of fittings with two, three or a large number of hollow correctly truncated pyramids with a coinciding longitudinal axis of symmetry, on the apofem of each of the side faces of which light-emitting diodes with optical axes perpendicular to these faces are mounted truncated pyramids.  2. The signal light according to claim 1, characterized in that each of the side faces of the hollow correctly truncated pyramids is perpendicular to the axis passing through the single optical center and the emitting center of the light emitting diode mounted on it, located on the longitudinal axis of symmetry of the fire.  3. The signal light according to claim 1 or 2, characterized in that the hollow correctly truncated pyramids are mounted on the armature of the holder coaxially within the angle at the apex of the lower pyramid and the side faces of each of them form channels for the passage of heated air. 4. Flashing light according to any one of claims 1 to 3, characterized in that the apofems of each of the side faces with light emitting diodes installed on them, at least one of the hollow correctly truncated pyramids within a half angle of 360 ^o / n, where n is the number of faces of the above lower truncated pyramid.  5. A signal light according to any one of claims 1 to 4, characterized in that the lower hollow correctly truncated pyramid of the holder armature for a group of light-emitting fire diodes is conjugated by a lower base with a ring-shaped concave element having a parabola profile, the focal circle of which coincides with the radiating centers of these diodes.  6. Flashing light according to any one of claims 1 to 5, characterized in that the outer surface of the side faces of each hollow correctly truncated pyramid is coated with a mirror-reflecting layer, for example, aluminum.  7. Flashing light according to any one of claims 1 to 6, characterized in that each hollow correctly truncated pyramid is made in the form of a figured shell mounted and curved on the edges of the truncated pyramid of the holder reinforcement.

Images