RU137699U1 - LED LAMP - Google Patents

Abstract

1. LED lamp containing a housing made of a light-transmitting shell with end caps that provide tightness of the housing, inside which a heat sink element is installed to provide heat removal from the lamp during operation, a printed circuit board with LEDs, an additional power source, characterized in that a radiator profile installed inside the housing, the profile and dimensions of which correspond to the profile and dimensions of the inner surface, is used as a heat sink element and cases for increasing the area and creating tight contact of the radiator profile with this surface, while the printed circuit board with LEDs is placed on the radiator profile. 2. The LED lamp according to claim 1, characterized in that, depending on the profile of the inner surface of the housing, the radiator profile can be made in the form of an I-beam. The LED lamp according to claim 1, characterized in that, depending on the profile of the inner surface of the housing, the radiator profile can be made round. The LED lamp according to claim 1, characterized in that, depending on the profile of the inner surface of the housing, the radiator profile can be made square or rectangular. The LED lamp according to claim 1, characterized in that the additional power source can be placed on the radiator profile. The LED lamp according to claim 1, characterized in that the radiator profile can be made of aluminum alloy. The LED lamp according to claim 1, characterized in that the printed circuit board can be made of aluminum or textolite. LED

Description

The utility model relates to the field of lighting engineering, in particular to lighting fixtures using universal-purpose LEDs with a distributed brightness along the length, and can be used as a stationary lamp for street or indoor lighting of mass application.

Known LED lamps, including a housing of various designs, inside of which there is a printed circuit board with LEDs placed behind a light-transmitting protective shield, a power source (patents RU: No. 83587 U1, IPC F21S 13/10, dated 20.01.2009, published on 06/10/2009, .; No. 85784 U1, IPC H05В 37/02, dated March 20, 2009, published on August 10, 2009; No. 88769 U1, IPC F21S 13/10, dated July 9, 2009, published on November 20, 2009; No. 90165 U1, IPC F21S 4/00, F21V 14/00, dated September 7, 2009, published on December 27, 2009; No. 92513 U1, IPC F21S 13/10, dated December 28, 2009, published on March 20, 2010; No. 92714 U1, IPC F21S 13/10, dated December 28, 2009, published March 27, 2010).

However, well-known fixtures are difficult to manufacture due to the need to perform fins on the outer surface of the casing, which acts as radiators to remove heat from the casing. The presence of fins on the housing complicates the design, leads to an increase in their mass, dimensions and, as a result, the cost of the fixtures increases. The service life of such lamps is limited as a result of their overheating. This is due to the fact that heat is removed from the internal volume of the housing by means of fins mounted on the outer surface of the housing. In addition, this form of radiators is subject to contamination over time on the fin surface, which leads to a deterioration in heat dissipation from the housing and negatively affects the life of the LEDs installed inside the housing. In addition, the presence of a large number of fins on the surface of the fixtures affects the possibility of long-term operation in aggressive environments.

The closest technical solution, selected as a prototype, is an LED module containing a housing made of a light-transmitting shell with end caps that ensure the tightness of the housing, inside of which there is a heat-removing element in the form of an air duct to ensure heat removal from the lamp during operation, on the external the surface of which contains a printed circuit board for the assembly of LEDs and an additional power source (Patent RU No. 2437128 C1, IPC G02B 6/00 (2006.01), dated June 17, 2010, published on June 17, 2010).

A disadvantage of the known module is the difficulty in sealing (which complicates the process of manufacturing fixtures), since it is necessary to ensure a tight fit of the end caps, both to the outer surface of the housing and to the duct located inside the housing. The execution of the duct from a hollow metal profile, for example, from an aluminum alloy does not allow the product to be operated in an aggressive environment due to the oxidation of aluminum on the inside of the duct in communication with the environment. The presence of oxidation leads to failure of the duct, which reduces the life of the module. The need to use air ducts increases the dimensions of the product as a whole, which leads to its appreciation. Due to the fact that the duct cavity communicates with the external environment, the inner surface of the duct is exposed to contamination, which leads to a decrease in the efficiency of heat removal from the lamp, overheating of the module during its operation and, as a result, to a decrease in the service life of the module as a whole.

The objective of the utility model is to increase the life of the LED lamp, reduce the cost and simplify its design, reduce the size, use it in aggressive environments, and increase the efficiency of heat removal from the lamp during operation by eliminating the possibility of overheating of the device from the operation of its elements.

This task is achieved by the fact that in the LED lamp containing the housing, made of a light transmitting shell with end caps, ensuring the tightness of the housing, inside of which there is a heat sink element for removing heat from the lamp in the process of its operation, a printed circuit board with LEDs, an additional power source, according to the claimed utility model, as a heat sink element using a radiator profile mounted inside the housing, the profile and dimensions of which correspond profile and dimensions of the inner surface of the housing to increase the area and create tight contact of the radiator profile with this surface, while the printed circuit board with LEDs is placed on the radiator profile.

Moreover, depending on the profile of the inner surface of the housing, the radiator profile can be made in the form of an I-beam.

Moreover, depending on the profile of the inner surface of the housing, the radiator profile can be made round.

In this case, depending on the profile of the inner surface of the housing, the radiator profile can be made square or rectangular.

In this case, the radiator profile can be made of aluminum alloy.

In this case, an additional power source can be placed on the radiator profile.

In this case, the printed circuit board can be made of aluminum or PCB.

In this case, the end caps are made of thermoplastic polymer material.

The installation of a radiator profile inside the lamp housing with a printed circuit board with LEDs on it contributes to a significant simplification of the lamp design due to its unification, reduction in size, and simplification of the production process, which reduces the cost of lamps in general.

The implementation of the surfaces of the radiator profile, the dimensions of which correspond to the geometry of the inner surface of the casing, leads to the creation of a tight contact of the profile with the inner surface of the casing and at the same time to an increase in the contact surface or contact area of the surfaces of the profile with the casing, which contributes to the efficient heat removal from the lamp during its operation As a result, the possibility of overheating is excluded and at the same time an optimal thermal mode of operation of the LEDs is created, which allows It is possible to increase the period of its operation and thereby ensure the service life declared by the LED manufacturer.

The implementation of the radiator profile of various shapes and sizes, for example, in the form of an I-beam, round shape, square or rectangular profile, depends on the modification of the manufactured luminaires in order to increase the contact surface, which ensures efficient heat removal from the luminaire during its operation and the creation of an optimal thermal operating mode LEDs extending its lifespan.

The implementation of the radiator profile of aluminum alloy, a printed circuit board of aluminum or textolite, plugs of thermoplastic polymeric material helps to reduce the size of the lamp, reduce the cost of the lamps and the possibility of their operation in aggressive environments, as well as eliminating the possibility of overheating of the lamp elements during its operation due to their technical properties and characteristics.

The proposed LED lamp is illustrated by drawings, where:

- in FIG. 1 shows an LED lamp, general view;

- in FIG. 2 is a section Α-A in FIG. 1 shows contact surfaces of a radiator profile with a housing;

- in FIG. 3 shows a profile of a round-shaped LED lamp in cross section;

- in FIG. 4 shows a rectangular cross-section of an LED luminaire.

The LED module includes:

1 - housing made of translucent material

2 - end caps

3 - radiator profile

4 - printed circuit board

5 - LEDs

6 - power supply or stabilization unit (option)

7 - cable

The LED lamp consists of a housing 1. The housing can be made in the form of a tube or profile of a square, rectangular, round or other cross-section of translucent material. As translucent material can be used: polycarbonate, polymethylmethacrylate, glass or other similar material that transmits light, which allows the operation of lamps in an aggressive environment due to the lack of oxidation. At the ends of the housing 1 installed end caps 2, which serve to seal the housing 1 (Fig. 1). Inside the housing 1, a heat sink element is installed in the form of a radiator profile 3 made, for example, of aluminum alloy. In cross section, the radiator profile 3 can be different, for example, in the form of an I-beam (Fig. 2), round shape (Fig. 3), square or rectangular (Fig. 4), or other type. In figures 3-4 shows the profiles of the LED lamp of circular shape and rectangular cross-section, but not limiting all possible options. The surface of the radiator profile 3 corresponds to the profile of the inner surface of the housing 1, and the dimensions of the profile 3 are made such that they provide the largest area of contact with the inner surface of the housing 1. The radiator profile 3 is fastened due to friction by its tight fit to the inner surface of the housing 1. B Depending on the geometry and sizes of the interacting surfaces of the radiator profile 3 and the housing 1, the largest contact area of these surfaces is created. A printed circuit board 4 is mounted on the outer surface of the radiator profile 3 with LEDs 5 evenly distributed along its entire length and an additional power source, for example, in the form of a power supply or stabilization unit 6, which is installed as an option. The lamp can both contain in its design an additional power source or stabilizer 6, and not contain. If you use an additional power source, then it can be located inside the lamp, and outside. An additional power supply has a shorter life and requires replacement of the lamp to replace it, which leads to a reduction in its service life. Therefore, to increase the life of the lamp, it is better to install an additional power source from the outside so that it can be changed without loss. In an example of a specific embodiment, a power supply unit 6 mounted inside the luminaire on the radiator profile 3 is used as an additional power source. The printed circuit board 4 can be made of aluminum or PCB, depending on the type and power of the installed LEDs and can have a different configuration to provide the necessary layout for to the housing 1 of the lamp. The power supply or stabilization unit 6 is connected to the printed circuit board 4 on the one hand, on the other hand connected to a cable 7 passing through an opening in the end cap 2 to an external power source (not shown). End caps 2 correspond to the profile of the housing 1 and can be made of any material, for example, polycarbonate, polypropylene, silicone rubber or other thermoplastic polymeric material. The dimensions of the plugs 2 and the holes for cable entry 7 are selected based on the requirements of tightness of the assembly and operation of the lamp.

LED lamp works as follows.

When you turn on the LED lamp from an external power source (not shown), the current through cable 7 passes through the plug 2 into the housing 1 and enters the power supply or stabilization unit 6. After conversion in block 6, the current flows to the circuit board 4 and LEDs 5, they light up . The light from the LEDs 5 penetrates through the translucent material of the housing 1. During operation, heat is emitted from the LEDs 5. The temperature of the radiator profile 3, on which the LEDs 5 are located, rises and is higher than the temperature of the housing 1. Due to the tight contact of the surface of the radiator profile 3 with the inner surface of the housing 1, heat from the radiator profile 3 is transferred to the lamp housing 1 and then to the environment, then there is a heat removal from the radiator profile 3. The amount of heat removed from the LEDs 5 depends on the configuration of the cross-section of the radiator profile 3, the thermal conductivity of the material used for profile 3 and housing 1, as well as the area of its contact with the housing 1. The geometric dimensions and configuration of the radiator profile 3 are determined based on the operating conditions of the lamp, the power of the installed LEDs 5, the thermal conductivity of the material of the radiator profile 3 and the housing 1. With the right choice of sizes and materials of the radiator profile 3 and the housing 1 is achieved reduction in the mass of the luminaire in comparison with similar known luminaires for the intended purpose. Radiator profile 3 can be made of standard profiles manufactured by the industry, which significantly reduces the cost of finished products. The luminaire has a simple design and allows for flexible configuration during production. When choosing the material of the housing 1 takes into account the aggressiveness of environmental influences, the operating conditions of the lamp, which allows it to be used in an aggressive environment, in conditions of high humidity and in rooms with a high dust content. The maximum contact surface of the radiator profile 3 with the inner surface of the luminaire housing 1 contributes to the efficient heat removal from the luminaire during its operation, which creates the optimal thermal mode of operation of the LEDs and extends the life of the LEDs.

Thus, the use of the proposed design of the radiator profile provides a stable temperature regime of the lamp and eliminates the possibility of overheating from the operation of its elements, which increases the life of the lamp as a whole. In addition, such a design allows you to easily change (increase or decrease) the length of the lamp, and the unification of the elements helps to reduce the cost of manufacturing various modifications of the lamps, reduce the cost and simplify the design, as well as reduce the dimensions of the lamps and the possibility of operation in aggressive environments. The simple geometry of the housing makes it easy to remove dirt from the luminaire and does not contribute to the settling of foreign particles.

Claims (8)

1. LED lamp containing a housing made of a light-transmitting shell with end caps that provide tightness of the housing, inside which a heat sink element is installed to provide heat removal from the lamp during operation, a printed circuit board with LEDs, an additional power source, characterized in that a radiator profile installed inside the housing, the profile and dimensions of which correspond to the profile and dimensions of the inner surface, is used as a heat sink element and housing to increase the area and create tight contact of the radiator profile with this surface, while the printed circuit board with LEDs is placed on the radiator profile. 2. The LED lamp according to claim 1, characterized in that, depending on the profile of the inner surface of the housing, the radiator profile can be made in the form of an I-beam. 3. The LED lamp according to claim 1, characterized in that, depending on the profile of the inner surface of the housing, the radiator profile can be made round. 4. The LED lamp according to claim 1, characterized in that, depending on the profile of the inner surface of the housing, the radiator profile can be made square or rectangular. 5. The LED lamp according to claim 1, characterized in that the additional power source can be placed on the radiator profile. 6. The LED lamp according to claim 1, characterized in that the radiator profile can be made of aluminum alloy. 7. The LED lamp according to claim 1, characterized in that the printed circuit board can be made of aluminum or textolite. 8. The LED lamp according to claim 1, characterized in that the end caps are made of thermoplastic polymer material.

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