RU77023U1 - LIGHTING DEVICE - Google Patents

Abstract

The lighting device relates to lighting technology, namely to fixtures designed for installation on the ceiling or wall to illuminate the entrances of buildings, landings and floor passages in residential buildings. The lighting device comprises a housing (1) with an LED board (5) installed in it, a light-transmitting shell (2). The novelty lies in the presence of side covers (3), in the execution of the housing (1) in the form of a box with a U-shaped cross section and the base (4) facing inward, as well as in fixing on the outside of the base (4) of the power supply case (1) (6). To effectively remove the heat generated by the LEDs (5) during operation, the base (4) of the housing (1) is in direct contact with the LED housings (5), the housing (1) is made of aluminum, and the surface area of the housing (1) is calculated from the condition: S _k ≥40 (cm ² ) × n, where S _k is the surface area of the body; n is the number of LEDs on the board. Installing a power source (6) directly in the device does not require additional connecting wires. The housing (1) is provided with tabs (7) with holes for fasteners for mounting the device on the ceiling or wall of a building. The light-transmitting shell (2) is made of impact-resistant polycarbonate, which protects the device from external damage. To increase the scattering angle, corrugation is applied to the inner side of the light transmission shell (2). The technical result consists in simplifying the design without reducing the heat sink efficiency and in improving the operating conditions of the device. 4 s.p. f-ly, 4 ill.

Description

The utility model relates to lighting engineering, namely to lamps intended for installation on a ceiling or wall to illuminate building entrances, stairwells and floor walkways in residential buildings.

When designing new types of lighting devices, LEDs (hereinafter referred to as LEDs) are used as a light source. One of the problems of such devices, especially those based on high-power LEDs, is the protection of LEDs from overheating. This is due to the fact that as a result of overheating of the LED, the light characteristics of the device deteriorate.

A lighting device is known that comprises a housing with an LED board installed in it, a light-transmitting shell and a power source installed outside the device housing (utility model, RF patent No. 37180, publ. 04/10/2004).

The specified device has the following disadvantages:

- the design of the device does not allow for efficient heat removal;

- the location of the power source complicates the operation of the device.

A lighting device is known that contains an LED mounted on a board mounted in the housing, contact elements, a power source and a heat removal unit, consisting of a layer of heat-conducting paste, a heat pipe and a radiator with longitudinal and transverse fins (utility model, RF patent No. 64321, publ. June 27, 2007).

The disadvantages of the known device include:

- the absence of a light-transmitting shell protecting the device from damage and providing standard lighting parameters;

- a complex design solution of the heat removal unit;

- low radiation power.

As the closest analogue, a lighting device containing a housing with an LED board installed in it and a light-transmitting shell was selected. Moreover, the outer wall of the housing is made with ribs and performs the function of a radiator (invention, US patent No. 6045240, publ. 04.04.2000).

The closest analogue housing design is laborious to manufacture and unacceptable for installation on a flat surface, such as a wall or ceiling. Heat removal from the LEDs to the radiator is carried out constructively from the terminals of the LEDs, which leads to low heat removal efficiency. In addition, the lack of an integrated power source complicates the operation of the device.

The task to which the claimed utility model is directed is to ensure the normative optical characteristics of the lighting device in various operating conditions and to increase reliability.

The technical result consists in simplifying the design while increasing the efficiency of heat removal and in improving the operating conditions of the device.

The problem is solved, and the technical result is achieved due to the fact that the lighting device comprises a housing with a LED board installed in it and a light-transmitting shell.

The novelty is that the lighting device is equipped with side covers, and the housing directly connected to the LED housings is made of heat-conducting material in the form of a box with a U-shaped cross section and a base facing inward. The surface area of the housing is determined from the condition:

S _to ≥S _E × n,

where S _to - the surface area of the housing;

S _E - the corrective value of the surface area of the body, determined experimentally and equal to 40 cm ² ;

n is the number of LEDs on the board.

In addition, a power source is installed on the outside of the base of the housing.

In addition, corrugation is applied on the inside of the light transmission shell.

In addition, the light-transmitting shell is made of impact-resistant polycarbonate.

In addition, the housing is equipped with tabs with holes for fasteners.

The essence of the claimed utility model is illustrated by drawings of a General view, presented in figures 1-4:

figure 1 is a front view;

figure 2 is a top view;

figure 3 is a bottom view;

figure 4 is a section aa in figure 1.

The lighting device comprises a housing (1), a light transmitting shell (2), side covers (3) (Fig. 1). The housing (1) is made in the form of a box with a U-shaped cross section and the base (4) facing inward (Figs. 3, 4). A board with ten powerful LEDs (5) is installed on the inner side of the base (4) (Fig. (2). To effectively remove the heat generated by the LED (5) during operation, the base (4) of the housing (1) directly contacts the LED housings ( 5), the housing (1) is made of aluminum, and the surface area of the housing (1) is calculated from the condition:

S _to ≥40 (cm ² ) × n,

where S _to - the surface area of the housing;

n is the number of LEDs on the board.

40 (cm ² ) - the correcting value of the surface area of the body, determined experimentally.

So, if the number of LEDs installed on the board is ten, then:

S _to ≥40 (cm ² ) × 10≥400 (cm ² )

On the outside of the base (4) of the housing (1), a power supply unit (6) is fixed (Fig. 3). Installing the power supply (6) directly in the device does not require additional connecting wires. The housing (1) is provided with tabs (7) with holes for fasteners for mounting the device on the ceiling or wall of a building (Fig. 3). The light-transmitting shell (2) is made of impact-resistant polycarbonate (Figs. 1-4), which protects the device from external damage. To increase the scattering angle, corrugation is applied to the inner side of the light transmission shell (2) (not shown conventionally in the drawings).

The device operates as follows.

A tape with a double-sided adhesive coating is applied to the inner side of the base (4) of the housing (1), onto which the power supply unit (6) is glued. Then, on the outside of the base (4), a heat-conducting tape is fixed and a LED board (5) is glued to it, and the wires are connected to the power supply (6), observing the polarity. After that, the light-transmitting shell (2) and side covers (3) are mounted on the housing (1) until they are in tight contact. The assembled lighting device is mounted on the ceiling or wall using fasteners, and the power supply unit (6) is connected to an alternating current network. The light from the LED (5) is distributed over the entire surface of the light-transmitting shell (2) and, falling on the corrugations made on its inner side, illuminates the surrounding area with a wide light beam with standard light characteristics.

Claims (5)

1. A lighting device comprising a housing with an installed board with LEDs and a light-transmitting shell, characterized in that it is additionally provided with side covers, and the housing directly connected to the LED housings is made of heat-conducting material in the form of a box with a U-shaped cross section and facing inward, while the surface area of the housing is determined from the condition S _to ≥S _E · n, where S _to - the surface area of the housing; S _E - the corrective value of the surface area of the body, determined experimentally and equal to 40 cm ² ; n is the number of light emitting diodes on the board. 2. The lighting device according to claim 1, characterized in that a power source is installed on the outside of the housing base. 3. The lighting device according to claim 1, characterized in that the light-transmitting shell is made of impact-resistant polycarbonate. 4. The lighting device according to claim 1, characterized in that the corrugation is applied on the inner side of the light transmission shell. 5. The lighting device according to claim 1, characterized in that the housing is equipped with tabs with holes for fasteners.