RU139896U1 - LED CEILING LIGHT - Google Patents

Abstract

1. LED ceiling lamp containing a housing made in the form of an elongated hollow profile of heat-conducting material with two longitudinal partitions forming a middle compartment, in the upper part of which there is a power supply, and two side compartments, as well as fixed on the lower side of the housing in its central parts of at least one circuit board with LEDs, each of the sides of the housing being made with at least one enclosure, characterized in that introduced to the end faces are the housing of the lid in the form of a transverse section of the casing, while in the lids in places adjacent to the side compartments of the casing, holes are made in the form of their transverse cuts, and on the underside of the casing under at least one board with LEDs a protective screen is made made of optically transparent material. 2. The device according to claim 1, characterized in that at least one board with LEDs is installed along the entire length of the lower side of the housing. The device according to claim 1, characterized in that the covers fixed to the end sides of the housing are made of heat-conducting material. The device according to claim 1, characterized in that the protective screen is made in the form of a rectangular flat plate in size of the lower side of the housing. The device according to claim 1, characterized in that the covers mounted on the end sides of the housing are configured to attach a protective shield to them. 6. The device according to claim 1, characterized in that the protective screen is made of polycarbonate. 7. The device according to claim 1, characterized in that the cross section of the housing has a trapezoidal shape. The device according to claim 1, ex

Description

The utility model relates to lighting devices and can be used for lighting inside office, administrative, public and technical premises.

Known LED lamp [RU 105968, U1, F21V 1/00, 06/27/2011], comprising a housing in which there are LEDs mounted on a board and connected to power supply, while the housing and board are made of aluminum, the sealing material is a light-conducting compound , which is poured at the level of the LED, the cover is a protective glass made, for example, of polycarbonate, and the housing is prefabricated.

The disadvantage of LED lighting is the lack of operational reliability due to low heat transfer to the environment.

Also known is a LED lamp [RU 112341, U1, F21S 8/00, 01/10/2012], contains a housing with a printed circuit board fixed to it, on which light-emitting diodes with an integrated primary optical system are placed, each of which has a secondary optical system, and a protective screen made of optically transparent material, moreover, on the inner surface of the protective screen an additional layer of optically transparent mass is deposited, having a relief formed by a combination of lenses made in a three-dimensional coordinate system in This surface layer which is a tertiary optical system.

The disadvantage of this LED lamp is also the lack of operational reliability due to the low heat transfer to the environment.

In addition, a known LED lamp [RU 118397, U1, F2S 88/00, 20.07.2012] containing a housing with a printed circuit board fixed to it, on which LEDs with an integrated primary optical system are placed, each of which has a secondary optical system, and there is also a protective screen, a power supply unit and a luminaire mounting unit in various operating conditions, while the housing is made of heat-conducting material and consists of two compartments, one compartment for accommodating the LED power supply, and the second compartment for accommodating LEDs with the possibility of efficient heat transfer, and, on the outer surface of the housing, longitudinal ribs are made, one housing compartment is made in the form of a segment of a hollow U-shaped metal profile with elements of a fixture attachment unit made together with the housing, and the second housing compartment is made in the form of a segment of a U-shaped metal profile, at the same time, the space between the secondary optical system and the protective shield made of metal is filled with sealing material, and the luminaire mounting unit is equipped with an additional bubbled elements and adapted to mount to the console street pole, a wall or a ceiling of a room or building.

This LED luminaire is also characterized by insufficient operational reliability due to low heat transfer to the environment.

The closest in technical essence to the claimed utility model is an LED lamp [RU 131450, U1, F21S 8/00, 08/20/2013], comprising a housing made in the form of a segment of a hollow profile of heat-conducting material with compartments, one compartment for accommodating a power supply , the second - with a board fixed in it with LEDs with sealing material, while the outer surface of the case is encircled, the first compartment contains partitions, and the power supply is installed in its upper part, in the second compartment the level of the location of the board is projections us.

The complication of the device due to the exposure of the outer surface of the housing and the implementation of the first compartment with partitions forming ventilated channels, allows to increase the heat transfer to the environment, which increases the term of reliable operation of the device.

However, the closest technical solution has inherent disadvantages associated with poor protection from environmental influences. This is because the case is made of a hollow profile and the board with LEDs is located in the lower part of the case and the LEDs directly interact with the external environment (dust, fumes, dirt, aggressive effects in industrial conditions, etc.). This reduces the heat transfer to the environment and, as a result, reduces the time of reliable operation of the device.

In addition, the hollow profile does not protect against external influences and the power supply. Due to air convection, dust and dirt particles are deposited on it, which complicates heat transfer and, as a result, reduces the time of reliable operation of the device.

The problem to which the proposed utility model is directed is to increase operational reliability.

The required technical result is to increase the operational reliability of the device by reducing the level of environmental impact on its active elements.

The problem is solved, and the required technical result is achieved by the fact that, in a device containing a housing made in the form of an elongated hollow profile of heat-conducting material with two longitudinal partitions forming the middle compartment, in the upper part of which is located the power supply, and two side compartments as well as at least one board with LEDs fixed on the lower side of the housing in its central part, wherein each of the sides of the housing is made with at least one enclosure, according to As well as the proposed utility model, lids fixed on the end sides of the housing are introduced, repeating its shape, while the covers are made in the form of transverse sections of the side compartments, and a protective screen is installed under at least one circuit board with LEDs on the underside of the housing, made of optically transparent material.

In addition, the required technical result is achieved by the fact that at least one board with LEDs is installed along the entire length of the lower side of the case.

In addition, the required technical result is achieved by the fact that, the covers mounted on the end sides of the housing are made of heat-conducting material.

In addition, the required technical result is achieved in that the protective screen is made in the form of a rectangular flat plate in size of the lower side of the housing.

In addition, the required technical result is achieved by the fact that, the covers mounted on the end sides of the housing are made with the possibility of attaching a protective shield to them.

In addition, the required technical result is achieved in that the protective shield is made of polycarbonate.

In addition, the required technical result is achieved in that the cross section of the housing has a trapezoidal shape.

In addition, the desired technical result is achieved by the fact that at least one embossment on each of the sides of the housing is made in the form of a smooth protrusion of the upper part of the side above the lower part.

The drawing shows:

in FIG. 1 - LED ceiling lamp (option with one enclosure on the sides of the housing), general view;

in FIG. 1 - LED ceiling lamp, cross section;

in FIG. 1 - LED ceiling lamp, view from the end cover.

The LED ceiling lamp comprises a housing 1 made in the form of an elongated hollow profile of heat-conducting material.

In the housing of the LED ceiling lamp, two longitudinal partitions 2 are made, forming the middle compartment 3, in the upper part of which a power supply unit 4 is placed, and two side compartments 5.

In addition, the LED ceiling lamp contains at least one board 6 with LEDs, mounted on the lower side of the housing 1 in its central part.

In the LED ceiling lamp, each of the sides of the housing 1 is made with at least one encirclement 7, and on the end sides of the housing 1 are fixed lids 8, repeating its shape.

The covers 8 are made with holes 9 in the form of cross sections of the side compartments 5, and on the lower side of the housing 1 under at least one board 6 with LEDs a protective screen 10 is made of optically transparent material.

In addition, one board 6 with LEDs can be installed along the entire length of the lower side of the housing 1 or contain a series of boards with LEDs. Covers 8, mounted on the end sides of the housing 1, can be made of heat-conducting material, for example, of the same material as the aluminum profile. The protective screen 10 can be made in the form of a rectangular flat plate in size of the lower side of the housing 1, and the covers 8, mounted on the end sides of the housing 1, can be made with the possibility of attaching to them a protective screen 10, which, in turn, can be installed on horizontal bends made on the lower edge of the profile. The protective screen can be made of polycarbonate. The cross section of the housing 1 may have a trapezoidal shape, and on each of the sides of the housing 1, at least one embossment 7 can be made in the form of a smooth protrusion of the upper part of the side above the lower part.

LED ceiling lamp operates as follows. When the luminaire is connected to the mains supply through the power supply unit 4, a constant stabilized current is supplied to the LEDs located on the board 6, ensuring their luminescence. The generated heat from the LEDs enters the housing 1. Due to the partitions 2, heat is evenly distributed on the outer surface of the housing 1. Effective heat exchange with the external environment is carried out not only due to the outer surface of the housing 1, but also thanks to the side compartments 5 in which natural air ventilation is carried out , arising due to the fact that the fixtures cannot be placed perfectly perfectly horizontally. Therefore, the heat, passing, previously, through the ventilated channels formed by the side compartments 5, is released by the surface of the housing 1 into the surrounding space, thereby ensuring high heat transfer of the device. In addition, the installation of the power supply 4 in the upper part of the middle compartment 3 provides for its effective cooling, which leads to an increase in its service life of the device.

Thus, the implementation of the housing 1 in the form of a segment of a hollow profile of a heat-conducting material having partitions provides uniform heating of the outer surface of the housing, which reduces the temperature difference between the LEDs and the outer surface of the housing and ensures an increase in its thermal conductivity. The enclosure of the outer surface of the housing and ventilated channels provide higher heat transfer to the surrounding space. Increasing the heat conductivity and heat transfer of the housing increases the life of the LEDs and the power supply, as well as reduce the metal consumption of the lamp.

In addition, through the use of a protective screen 10 and end caps 8, the operational reliability of the device is increased, since the direct impact of negative environmental factors (dust, fumes, dirt, aggressive effects in an industrial environment, etc.) on a board 6 with LEDs is eliminated. which is located in the lower part of the housing 1. In addition, thanks to the end caps 8, the power supply unit 4 is also protected from the effects of negative environmental factors. At the same time, due to the fact that the covers 8 fixed to the end sides of the housing are made with holes 9 in the form of transverse cuts of the side compartments 5, ventilation is still possible in these compartments, which are ventilated channels.

Claims (8)

1. LED ceiling lamp containing a housing made in the form of an elongated hollow profile of heat-conducting material with two longitudinal partitions forming a middle compartment, in the upper part of which there is a power supply, and two side compartments, as well as fixed on the lower side of the housing in its central parts of at least one circuit board with LEDs, each of the sides of the housing being made with at least one enclosure, characterized in that introduced to the end faces are the housing of the lid in the form of a transverse section of the case, while in the lids in places adjacent to the side compartments of the case, holes are made in the form of their transverse sections, and on the underside of the case under at least one board with LEDs a protective screen is made made of optically transparent material. 2. The device according to claim 1, characterized in that at least one board with LEDs is installed along the entire length of the lower side of the housing. 3. The device according to p. 1, characterized in that the covers mounted on the end sides of the housing are made of heat-conducting material. 4. The device according to p. 1, characterized in that the protective screen is made in the form of a rectangular flat plate in size of the lower side of the housing. 5. The device according to p. 1, characterized in that the covers mounted on the end sides of the housing are configured to attach a protective shield to them. 6. The device according to claim 1, characterized in that the protective screen is made of polycarbonate. 7. The device according to p. 1, characterized in that the cross section of the housing has a trapezoidal shape. 8. The device according to p. 1, characterized in that at least one embossment on each of the sides of the housing is made in the form of a smooth protrusion of the upper part of the side above the lower part.

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