RU103895U1 - LIGHTING STREET SEMICONDUCTOR - Google Patents

Abstract

 1. Street semiconductor lamp, comprising a housing, the outer surface of which is a cooling radiator, semiconductor light sources, a light source control unit, a protective optically transparent element, characterized in that on the lower side of the housing there is a system of reflective screens parallel to the rows of semiconductor emitting elements. ! 2. The lamp according to claim 1, in which the reflective screen is made of at least two rectangular plates, the cross section of which is described by a broken line consisting of at least two segments. ! 3. The lamp according to claim 1, in which the reflective screen is made of at least two rectangular plates, the cross section of each of which is described by a second-order curve.

Description

The utility model relates to light sources and is intended for lighting roads, highways, streets, squares, courtyards, etc.

With the advent of LED light sources with high light output, low weight, low power consumption, high service life, LED lighting devices have become widespread. LED light sources have found their application in street lamps.

Known street LED lamp (patent for PM RU No. 90877), comprising a heat sink housing with fins and placed therein on a convex surface, LED arrays with a protective optically transparent polycarbonate element with ribs that clamp the LED arrays on the other hand. The disadvantages of this lamp include poor cooling of LED arrays placed on a convex surface and other elements heated by electric current, the inability to form the necessary light distribution in space.

A known design of a transformable energy-saving LED lamp (patent for PM RU No. 91617). This lamp is interesting in that it contains a double-sided mounting unit for unified replaceable LED blocks that can be rotated around its axis in order to form the required general radiation pattern of the entire lamp. The weak point of this lamp is the reliability of the fasteners and the convenience of its implementation. The position of the screws of the mounting unit of the LED blocks during long-term operation can weaken, for example, from vibration, primarily in luminaires for illuminating highways, which will lead to a deterioration in the uniformity of illumination of the roadway.

Closest to the claimed technical solution is a utility model of a street LED lamp (patent for PM RU No. 83587), mounted on a support containing a housing with a light source installed inside and a power supply, the entire surface of the housing of which is a cooling radiator made in the form of fins . The light source is an LED module in which light-emitting elements are combined in parallel lines of series-connected heavy-duty LEDs. The luminaire also has a temperature sensor and a control system for the emitted power of the LEDs depending on atmospheric temperature. The disadvantages of this lamp include the lack of means of formation and regulation of the radiation pattern to ensure uniform illumination in various conditions.

The task this utility model is aimed at is to create an economical LED street lamp for uniform illumination of highways, roads, open spaces, providing the necessary lighting parameters in a wide spatial direction and with a high degree of operational reliability.

The problem is solved in that in the street LED lamp (Figure 1), mounted on a support and consisting of a housing 1, the upper surface of which is made in the form of fins 2, and on the inner surface of the housing there are rows of powerful emitting LED matrices 3, parallel to the rows of the emitting matrices on the radiating surface of the luminaire there are reflecting screens 4. The number, location and shape of the reflecting screens are due to the fact that for uniform illumination of the motorway the luminaire must have a curve Depending luminous intensity (CIL) from "W" type wide angle of radiation, called the QRS type. The introduction of reflective screens into the design of the lamp allows you to achieve the desired distribution of radiation in the most simple and reliable way. From the side of the light-emitting elements, the lamp is protected by an optically transparent element 5, and on the back side of the lamp there is a control unit for light sources 6. The circuit of the lamp control unit is shown in FIG. 2.

In the particular case, each reflective screen 1 (Fig.3a) is a rectangular plate, which in cross section is described by a second-order curve.

In another embodiment, the cross-sectional curve of the screen 1 can be represented in the form of a broken line, consisting of at least two straight line segments (Fig.3b.).

KSS view for a street LED lamp is shown in Figure 4.

The technical result of the claimed utility model is the creation of an economical reliable street LED lamp providing uniform illumination of roads and highways.

An example of practical implementation. A batch of street LED lights was made on this proposal in the amount of 20 pcs. The light source was a group of 18 pieces. LED matrices with an area of 18 × 18 mm ² . All matrices were electrically interconnected in series. The monolithic housing of the street semiconductor lamp was made of aluminum. The built-in stabilizer provided at a voltage of 220 V a set current value of 600 mA. The luminous flux of the manufactured street semiconductor luminaires was at least 10,000 lm with a consumed power supply network of not more than 120 watts.

Claims (3)

1. semiconductor street lamp comprising a housing, the outer surface of which is a cooling radiator, the semiconductor light sources, the light source control unit, a protective optically transparent element, characterized in that on the underside of the housing parallel to the rows of semiconductor emitting element is a system of reflective displays. 2. The lamp according to claim 1, in which the reflective screen is made of at least two rectangular plates, the cross section of which is described by a broken line consisting of at least two segments. 3. The lamp according to claim 1, in which the reflective screen is made of at least two rectangular plates, the cross section of each of which is described by a second-order curve.