RU136123U1 - LANDSCAPE LED LIGHT INSTRUMENT (OPTIONS) - Google Patents

Abstract

1. Landscape LED lighting device, comprising a cylindrical body, a diffuser, a heat-conducting base with LED light sources, characterized in that the LED light sources are arranged around a circle near the diffuser on a flat heat-conducting base in the form of a disk with a variable cross-section, which is part of a heat-conducting tube located perpendicular to its axis and having cooling fins made of heat-conducting material inside, while between the optical axis of the LED light source and a mirror is located on the surface of the heat-conducting tube, the plane of which is parallel to the optical axis of the LED light source. 2. A landscape LED lighting device comprising a cylindrical body, a diffuser, a heat-conducting base with LED light sources and a reflector, characterized in that the LED light sources are arranged in a circle around the diffuser on a flat heat-conducting base in the form of a disk with a variable cross-section, which is part of a heat-conducting tube located perpendicular to its axis and having cooling fins made of heat-conducting material inside, while between the optical axis of the LED source the light source and the surface of the heat-conducting tube there is a mirror with the possibility of changing the inclination of its plane, and the reflector located under the mirror is fixed at one end to the tube and rests on the plate with holes at the other. 3. A landscape LED light fixture including a cylindrical housing, a diffuser, a heat-conducting base with LED light sources and

Description

The utility model relates to lighting engineering and can be used both for landscape lighting and lighting of pedestrian and garden areas.

A well-known landscape gardening lamp (ground lamp), for example, NFB 82 LED of the Lighting Technologies company, consists of a cylindrical body, an upper spherical part with a diffuser, a mounting plate on which there is a cone-shaped reflector and an LED whose radiation is directed to the inner surface of the upper spherical part [http://www.ltcompany.com/files/catalog/passport/437_ru.pdf], [http://www.ltcompany.com/files/catalog/catalog/437_ru.pdf].

The disadvantages of this design of the light device is its low value of light efficiency equal to 29%, due to double diffuse reflection of the light flux of the LED in the process of its exit from the lamp: the first is reflection from the inner surface of the upper spherical part of the lamp; the second from the outer surface of the conical reflector.

The technical result consists in increasing the light efficiency of the light device.

The technical result is achieved by the fact that the landscape LED lighting device comprises a cylindrical body, a diffuser, a heat-conducting base with LED light sources located around a circle near the diffuser on a flat heat-conducting base in the form of a disk with a variable cross section, which is part of a heat-conducting tube located perpendicular to its axis and having cooling fins made of heat-conducting material inside. A mirror is located between the optical axis of the LED light source and the surface of the heat-conducting tube, the plane of which is parallel to the optical axis of the LED light source.

In a second embodiment, the device comprises a cylindrical body, a diffuser, a heat-conducting base with LED light sources and a reflector. LED light sources are located around the circumference near the diffuser on a flat heat-conducting base in the form of a disk with a variable cross-section, which is part of a heat-conducting tube located perpendicular to its axis and having cooling fins made of heat-conducting material inside. Between the optical axis of the LED light source and the surface of the heat-conducting tube there is a mirror with the possibility of changing the inclination of its plane, and the reflector located under the mirror is fixed at one end to the tube and rests on the plate with holes at the other.

In a third embodiment, the device comprises a cylindrical body, a diffuser, a heat-conducting base with LED light sources and a reflector. LED light sources are located around the circumference near the diffuser on a flat heat-conducting base in the form of a disk with a variable cross-section, which is part of a heat-conducting tube located perpendicular to its axis and having cooling fins made of heat-conducting material inside. A reflector having different angles of the parts of the cone is fixed at one end to the tube, and the other rests on a plate with holes.

In all three variants, ventilation holes are made in the housing and in the upper part of the diffuser. The diffuser consists of two parts of the lower transparent and upper matte. Above the upper part of the diffuser there is a cover at a distance determined by the following ratio:

L≥d / 4,

where: L is the distance from the surface of the upper portion of the diffuser to the inner surface of the cover;

d is the minimum value of the inner diameter of one of the tubes. The location of the longitudinal planes of the LED light sources on a heat-conducting base can vary with the possibility of adjusting the light intensity.

Figure 1 shows the design of a landscape LED lighting device; figure 2 is a sectional view taken along section AA; figure 3 - design with mirrors and a reflector; figure 4 design with a cone-shaped reflector of variable curvature; figure 5 is a sectional view taken along the cross-section AA in the case of a non-symmetrical arrangement, relative to the longitudinal axis of the lamp, of LED light sources on a heat-conducting base.

The landscape LED light fixture (Fig. 1) contains a cylindrical body 1, in the upper part of which there is a diffuser, consisting of two sections: the lower 2 - transparent and the upper 3 - matte of diffusely scattering material, for example, milk glass. Inside the cylindrical body 1, approximately at the border of the lower 2 and upper 3 sections of the diffuser, on a flat heat-conducting base 4 there are LED light sources 5, the optical radiation of which is directed to the lower hemisphere. LED light sources 5 on the heat-conducting base 4 are located around the circumference near the diffuser (figure 2). The location of the longitudinal planes of the LED light sources 5 on the heat-conducting base 4 may vary with the possibility of adjusting the light intensity (figure 5). The heat-conducting base 4 in the form of a disk with a variable cross-section is a part of the heat-conducting tube 6, inside of which there are cooling fins 7 made of heat-conducting material. The heat-conducting tube 6 is connected from above to the tube 8, on which the diffuser and the lid 9 of the light fixture are fixed in the form of an umbrella of transparent or opaque material at a certain distance from the upper portion 3 of the diffuser. The cover 9 is located above the upper part 3 of the diffuser at a distance determined by the following ratio:

L≥d / 4,

where: L is the distance from the surface of the upper portion 3 of the diffuser to the inner surface of the cover 9;

d is the minimum value of the inner diameter of one of the tubes 6, 8 or 10. From below, the heat-conducting tube 6 is connected to the tube 10, which is fixed in the holes of the plates 11 and 12, which, in turn, are attached to the cylindrical body 1 of the light device. In the cylindrical body 1 and in the upper part 3 of the diffuser, air holes 13 are made for air passage.

In the first embodiment (Fig. 1), a mirror 16 is located between the optical axis 14 of the LED light source 5 and the surface 15 of the heat-conducting tube 6, the plane of which is parallel to the optical axis 14 of the LED light source 5.

In the second embodiment (figure 3) between the optical axis 14 of the LED light source 5 and the surface 15 of the heat-conducting tube 6 is a mirror 16 with the possibility of changing the inclination of its plane. Under the mirror 16 is a reflector 17, one end mounted on a tube 6, and the other resting on a plate with holes 11.

In the third embodiment (Fig. 4), between the optical axis 14 of the LED light source 5 and the surface 15 of the heat-conducting tube 6 is a reflector 18 having different angles of the cone parts and fixed at one end to the tube 6 and resting on the plate with holes 11 by the other.

Landscape LED lighting device operates as follows (figure 1). When a supply voltage is applied to the light device, the LED light sources 5 begin to emit optical radiation. LED light sources 5 have different light distribution in different planes: in the longitudinal plane there is a wide or semi-wide type of light intensity curve (KCC), and in the transverse plane perpendicular to the longitudinal, cosine or close to it type of KSS. Since the longitudinal plane of the radiation of the LED light sources 5 passes through the center of the cylindrical body 1 (Fig. 2), then the LED light sources 5 direct the light flux in different directions relative to the optical axis 14. Therefore, between the optical axis 14 of the LED light sources 5 and the surface 15 is heat-conducting tube 6 is a mirror 16, reflecting the radiation of the LED light sources 5, directed towards the tube 6 in the opposite direction, that is, through the lower transparent part 2 of the diffuser to the outside of the light ribo. In this case, the intensity of a wide or half-wide KSS of the LED light source emerging from the light device increases by 70-80%. By changing the inclination of the plane of the mirror 16, it is possible to set the angle of exit of radiation from the light device and thereby control the range of the beam of the LED light sources 5, which is very important when the terrain is not horizontal. In the second case, part of the radiation of the LED light source 5 propagates along its optical axis 14. For the rational use of this fraction of the radiation, a reflector 17 is installed opposite the LED light source 5 (Fig. 3), which directs this radiation in the horizontal direction. In the third case, the uniform distribution of the light flux around the light fixture instead of the mirror 16 and the reflector 17, it is advisable to use a reflector 18 having different angles of the parts of the cone (figure 4). Landscape LED lighting device allows, in addition, to adjust the light intensity in accordance with the desired configuration of the illuminated area by changing the location of the longitudinal planes of the LED light sources 5 (figure 5).

LED light sources 5 during operation emit thermal energy, so they are installed on a heat-conducting base 4, which transfers thermal energy to the tube 6 from a heat-conducting material, inside which there are cooling fins 7. The air inside the tube 6 and in contact with the cooling fins 7 is heated and, due to convection, rises up, flows through the tube 8 and through the gap between the diffuser and the cover 9 goes into the surrounding space.

The distance L from the surface of the upper portion 3 of the diffuser to the inner surface of the cover 9 is determined by the following relationship:

L≥d / 4,

where d is the minimum value of the inner diameter of one of the tubes 6, 8 or 10.

In place of the heated air, due to convection, colder air enters from the environment through the tube 10 and ventilation holes 13 in the housing 1 of the light device.

Compared with the known solution, the proposed one allows to increase the luminous efficiency of the light device.

Claims (7)

1. Landscape LED lighting device, comprising a cylindrical body, a diffuser, a heat-conducting base with LED light sources, characterized in that the LED light sources are arranged around a circle near the diffuser on a flat heat-conducting base in the form of a disk with a variable cross-section, which is part of a heat-conducting tube located perpendicular to its axis and having cooling fins made of heat-conducting material inside, while between the optical axis of the LED light source and a mirror is located on the surface of the heat-conducting tube, the plane of which is parallel to the optical axis of the LED light source. 2. Landscape LED light device, comprising a cylindrical body, a diffuser, a heat-conducting base with LED light sources and a reflector, characterized in that the LED light sources are located around a circle near the diffuser on a flat heat-conducting base in the form of a disk with a variable cross-section, which is part of a heat-conducting tube located perpendicular to its axis and having cooling ribs of heat-conducting material inside, while between the optical axis of the LED regular enrollment light and the surface of the heat-conducting tube disposed mirror with the possibility of changing the inclination of its plane, and a reflector disposed under the mirror, at one end fastened to the tube, and the other rests on a plate with holes. 3. Landscape LED lighting device, comprising a cylindrical body, a diffuser, a heat-conducting base with LED light sources and a reflector, characterized in that the LED light sources are located around a circle near the diffuser on a flat heat-conducting base in the form of a disk with a variable cross-section, which is part of a heat-conducting tube located perpendicular to its axis and having cooling ribs of heat-conducting material inside, with a reflector having different angles of frequent her cone, fixed at one end to the tube, and the other rests on a plate with holes. 4. Landscape LED lighting device according to any one of claims 1 to 3, characterized in that the ventilation holes are made in the housing and in the upper part of the diffuser. 5. Landscape LED lighting device according to any one of claims 1 to 3, characterized in that the diffuser consists of two parts of the lower transparent and upper matte. 6. Landscape LED lighting device according to any one of claims 1 to 3, characterized in that a cover is located over the upper part of the diffuser at a distance determined by the following ratio: L≥d / 4, where L is the distance from the surface of the upper portion of the diffuser to the inner surface of the cover; d is the minimum value of the inner diameter of one of the tubes. 7. Landscape LED lighting device according to any one of claims 1 to 3, characterized in that the arrangement of the longitudinal planes of the LED light sources on a heat-conducting base can vary with the possibility of adjusting the light intensity.

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