RU154074U1 - LED LAMP - Google Patents

Abstract

LED general lighting lamp, including a base, a transitional insulating element of dielectric plastic connected to it with a cavity inside, in which there is a power supply for the lamp to work in electrical networks, connected to LED modules made on a printed circuit board with a heat-conducting metal base and mounted on a radiator , the radiator has a central part of the rod profile of the section and ribs, while the central part of the radiator is made with side faces directed in different directions, on which these LED modules are placed, and placed inside a diffuser made of plastic, close to glass in optical characteristics, characterized in that the diffuser is made with external surface sections extending in the direction from the base and internal sections recessed located between the surfaces, opposite of which LED modules are placed inside the diffuser on the sides of the radiator, the radiator is made with longitudinally oriented fins located at least in part s of the radiator and extending from the surface of the central part of the radiator between its faces to form heat sink surfaces, and the diffuser is a cap made in the form of longitudinally oriented segmented shells, or the diffuser is made in the form of separate longitudinally oriented segmented shells, each of which is opposite the LED modules of one facets of the central part of the radiator and covers them with isolation of these LED modules from the LED modules on an adjacent

Description

The utility model relates to the field of lighting, in particular, to lighting devices and is intended for use in household and industrial lighting fixtures for a wide range of purposes.

The main distinguishing feature of the LED lamp is the distribution of its luminous flux in the surrounding space. Subject to the generally accepted, for incandescent lamps, shapes and dimensions, the LED lamp has a uniformly distributed scattered light, unlike most modern LED lamps, the angle of which does not correspond to the lamps they replace.

Thus, a general-purpose LED lamp is known, including a base, an adapter element (insulator) connected to it, made of dielectric plastic with an additional cavity in the center, in which there is a power supply for the lamp to work in electrical networks, connected to an LED module made on a printed a board with a heat-conducting metal base mounted on a radiator, the radiator is made in the form of a rod profile of a complex section having side planes directed in different directions and on which LED modules are placed, while the radiator is placed inside a diffuser made of plastic, close to glass in optical characteristics, in which the LED modules on each face of the radiator are located opposite the sections of the diffuser located between the radial protrusions on this diffuser (US 2012/0313518, H01K 1/62, H05K 13/00, H01J 61/52, publ. 13.12.2012).

The process of formation of distributed scattered light in such an LED lamp is that the light from the LED module passes through a thin wall of transparent plastic into the environment, while part of this light enters the walls of the radial protrusions and is reflected from their surface. Thus, the combination lighting of the space in the 360 ° zone around the diffuser is provided.

The diffuser has a complex spatial shape of the shell with radial ribs, while in the center of the shell, on the opposite side of the base, there is a through hole for removing heat from the radiator. But such a method of heat removal is inefficient, since it does not provide heat removal from the entire surface of the rod element, which is a radiator. At the same time, the radiator in the lower part is adjacent to the power supply located on the base of the LED modules. In this regard, in the lower part of the radiator has constant overheating, and removal from the upper part of the radiator through a hole of constant cross-section by convection in the diffuser is not very effective. The presence of increased heat in the lower part of the radiator leads to the fact that this heat acts on the plastic of the diffuser. Even when using plastic such as polycarbonate (light transmission - transparency - up to 86%), resistant to a wide range of high temperatures (up to 120 ° C), constant heating leads to clouding of the structure of the material, which affects the quality of light scattering of the light flux of LEDs. For polycarbonate, special coatings are used to reduce the effect of thermal radiation on the structure of the material, but not always these coatings can be used for lighting.

It is known that the efficiency of high-power LEDs is an order of magnitude higher than that of incandescent lamps. At the same time, most of the energy consumed by the LEDs (about 75%) still goes into dissipated heat. With an increase in the luminous flux from LED sources, heat generation increases. According to some international and domestic experts, ensuring effective heat dissipation in light-emitting diode (LED) lighting technology is one of the most urgent tasks facing developers and manufacturers of these products today.

Unlike traditional incandescent and discharge lamps, modern LEDs are sensitive to high temperatures:

- firstly, when an LED overheats, its efficiency decreases, the luminous flux decreases, the color temperature changes, and the service life can be reduced significantly;

- secondly, at a temperature of 80 ° C, the intensity of the glow decreases by about 15% compared with the intensity at room temperature. As a result, a luminaire with twenty LEDs at 80 ° C can have a luminous flux equivalent to that of seventeen LEDs at room temperature. At a transition temperature of 150 ° C, the light intensity of the LEDs can drop by 40%.

- thirdly, the LEDs have a negative temperature coefficient of direct voltage, i.e. as the temperature rises, the forward voltage of the LEDs decreases. Typically, this coefficient ranges from -3 to -6 mV / K, so the direct voltage of a typical LED can be 3.3 V at + 25 ° C and not more than 3 V at + 75 ° C. If the power source does not allow reducing the current on the LEDs, then this can lead to even more overheating and failure of the LEDs. In addition, many power supplies for LED luminaires are designed for operating temperatures up to + 70 ° C.

Thus, for the efficient operation of many LED devices, it is important to ensure a temperature of no more than 80 ° C both in the p-n junction region of the LEDs and in the area of the power source. Failure to comply with the recommended temperature regime can lead to a loss in the quantity and quality of light, an increase in the cost of light from an LED device, and also a decrease in the life of a lighting device.

This utility model is aimed at achieving a technical result consisting in increasing the operational reliability of an LED lamp by providing efficient heat dissipation from the entire surface of the radiator over its entire height.

The specified technical result is achieved in that in the LED lamp of general lighting, including the base, the transitional insulating element of dielectric plastic connected to it with a cavity inside, in which there is a power supply for the lamp to work in electrical networks, connected to LED modules made on a printed circuit board with a heat-conducting metal base, and mounted on the radiator, the radiator has a central part of the rod profile of the section and fins, while the central part of the radiator is with lateral faces directed in different directions on which the indicated LED modules are placed and placed inside a diffuser made of plastic with optical characteristics close to glass; the diffuser is made with external surface sections extending in the direction from the base and internal sections recessed located between the surfaces opposite which LED modules are placed inside the diffuser on the sides of the radiator, the radiator is made with longitudinally oriented fins, located at least part of the height of the radiator and extending from the surface of the central part of the radiator between its faces to form heat sink surfaces, and the diffuser is a cap made in the form of longitudinally oriented segmented shells, or the diffuser is made in the form of separate longitudinally oriented segmented shells, each of which is located opposite the LED modules of one face of the central part of the radiator and covers them with isolation of these LED modules from LED m a module on an adjacent face, with longitudinally oriented fins of the radiator located between the segmented shells.

These features are significant and are interconnected with the formation of a stable set of essential features sufficient to obtain the desired technical result.

The present utility model is illustrated by a specific example of execution, which, however, is not the only possible one, but clearly demonstrates the possibility of achieving the required technical result.

In FIG. 1 - a general view of the LED lamp for installation in standard electrical cartridges (electrons) E27 (E14);

FIG. 2 is a view of the lamp from the side of the transparent portion of the diffuser on the LED modules;

FIG. 3 - shows the distribution of heat over temperature along the height of the radiator;

FIG. 4 - shows the distribution of heat over temperature over the cross section of the radiator.

According to this utility model, the design of an LED lamp for general lighting, designed for installation in standard electric cartridges (electrons) E27 (E26, E14, E12, E17, B22d, B15d), is considered. This lamp is made in standard (common / familiar) sizes to replace the corresponding utilitarian light sources. Under the diffuser made of lighting plastic, there are lighting modules, which are single-sided printed circuit boards of increased thermal conductivity with LEDs evenly spaced on them, switched on according to a combined circuit. The LEDs in the modules are arranged in such a way that a uniform distribution of the light flux from the lamp in all directions in space (360 °) is created. A power supply unit is located in the housing and lamp base for operation in 220 V / 50 Hz AC electric networks. The main task solved by the proposed utility model is the creation of an LED lamp with high operational reliability, increased lighting efficiency (due to the uniform distribution of the light flux in all directions).

The LED general lighting lamp (Figs. 1 and 2) includes a socle 1, a transitional insulating element 2 (insulator) connected to it, made of dielectric plastic with a cavity inside, in which there is a power supply 3 for the lamp to operate in electrical networks. This power supply is connected to the LED modules 4, made on a printed circuit board with a heat-conducting metal base, and mounted on the radiator 5.

The radiator 5 has a central part of the rod profile of the cross section with side faces 6 directed in different directions and on which these LED modules 4 are placed.

The radiator 5 is placed inside the diffuser 7, made of plastic, with optical characteristics close to glass. The radiator is made with longitudinally oriented ribs 8 located at least on a part of the height of the radiator and extending from the surface of the radiator between the faces to form heat sink surfaces. The radiator is made in the form of a complex section profile with longitudinally oriented ribs located on the outside lying in planes passing through the axis of the lamp. Preferably, the radiator is made of aluminum, or light alloys of aluminum, copper or ceramic.

The diffuser 7 is a cap made in the form of longitudinally oriented segmented shells 9, or the diffuser is made in the form of separate longitudinally oriented segmented shells 9 of various shapes (depending on the type of lamp), each of which is opposite the LED modules 4 of one face 6 and covers them isolating these LED modules from the LED modules on an adjacent face. The diffuser of complex shape in vertical section is the shape of a conventional lamp (A60, C37, G45, P45, etc.), and is made of plastic that is close to glass in optical characteristics, for example, polycarbonate.

A longitudinally oriented fins 8 of the radiator are located between the segmented shells 9 so that part of the radiator with LEDs is located inside the group of diffusers. A radiator made in the form of a complex section profile with longitudinally oriented ribs located on the outside lying in planes passing through the axis of the lamp is installed in the grooves of the housing made of dielectric plastic and mechanically fixed to it, while the housing is also mechanically connected to the insulator basement. Through-holes 10 are made in the insulator for additional heat removal from the area where the power supply is located.

The LEDs in the LED lamp are divided into several groups (modules) interconnected in series or parallel or series-parallel or parallel-series circuit. The LED modules are made with heat-conducting metal bases and are mounted on the radiator body, while the modules are located in such a way as to ensure uniform distribution of the light flux in the internal volume of the diffuser segments and, as a result, the total light flux of the lamp. The LEDs on the board are arranged in such a way as to provide uniform end illumination of the material of the diffusers.

Thus, a feature of the LED lamp according to this utility model is that the LEDs on each face of the radiator are located in their own transparent shells, direct radiation to the end surface and to the side surfaces of the shell. But it should be borne in mind that the most common way to remove excess heat from high-power LEDs and microchips is to transfer it to a printed circuit board (including boards with a metal base - MS RSV, AL RSV, IM RSV), a substrate, or other structural elements electronic device. The installation of a radiator on an overheating component (or an overheating component on a radiator) is also used, which increases the area of radiant and convection exchange. Then the heat is transferred to the environment mainly by convection. But in reality, the surface of the heat source and heat sink have roughness and roughness. When the planes come into contact in most cases, gaps (microcavities) arise, in which air is contained. As a result, the contact between the planes occurs pointwise, which significantly increases the thermal resistance of the transition. It is important to remember that air has a thermal conductivity of about 0.02 W / m · K, which is extremely small and about 40 times less than typical heat-conducting pastes. Thus, due to the presence of air between the contacting surfaces, a high resistance to heat flow occurs, and the efficiency of heat dissipation decreases significantly. To avoid this negative effect from the presence of air, a heat-conducting material is used that fills the gaps. In this case, the heat from the module is contactlessly transferred to the radiator. In this case, the heat sink is carried out through the ribs, which are brought out and laid out outside the segments. Thus, there is no increase in temperature inside the segmented membranes above the established norm. Studies have shown (see Fig. 3 and 4). that during long-term operation of the LED lamp, the temperature of the radiator and its ribs brought out does not exceed 61 ° C, and the temperature inside the segmented shells is approximately in the region of 40 ° C. Such indicators indicate the absence of overheating of the LEDs on the radiator. Thus, the efficiency of the LEDs and the luminous flux is maintained, it is maintained at a qualitative level without changing the color temperature.

Claims (1)

LED general lighting lamp, including a base, a transitional insulating element of dielectric plastic connected to it with a cavity inside, in which there is a power supply for the lamp to work in electrical networks, connected to LED modules made on a printed circuit board with a heat-conducting metal base and mounted on a radiator , the radiator has a central part of the rod profile of the section and ribs, while the central part of the radiator is made with side faces directed in different directions, on which these LED modules are placed, and placed inside a diffuser made of plastic, close to glass in optical characteristics, characterized in that the diffuser is made with external surface sections extending in the direction from the base and internal sections recessed located between the surfaces, opposite of which LED modules are placed inside the diffuser on the sides of the radiator, the radiator is made with longitudinally oriented fins located at least in part s of the radiator and extending from the surface of the central part of the radiator between its faces to form heat sink surfaces, and the diffuser is a cap made in the form of longitudinally oriented segmented shells, or the diffuser is made in the form of separate longitudinally oriented segmented shells, each of which is opposite the LED modules of one facets of the central part of the radiator and covers them with isolation of these LED modules from the LED modules on an adjacent Rani, the longitudinally oriented fins are arranged between the segmental shells.

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