RU200123U1 - LED LAMP WITH MOLDED BODY-RADIATOR - Google Patents

Abstract

The utility model relates to lighting engineering, namely to LED lamps powered directly from the alternating current network. The technical result is to simplify the design, improve heat dissipation and reduce the labor intensity of manufacturing high-power lamps of general use, resistant to external influences> IP65, and with a minimum cost and labor intensity. Contains a radiator housing made in the form of a hollow cylindrical body made of optically transparent material; the only flexible aluminum PCB with LEDs and driver mounted on the mounting surface; end caps, at least one of which is provided with means for connecting to the power supply network, while the flexible printed circuit board is configured in the form of a cylinder, with the mounting surface outward, and part of the driver board is bent inside the cylinder, and the LEDs and the mounting surface of the configured printed circuit board are embedded into the body of the transparent part of the radiator housing, forming a single whole. 5 p.p. f-ly, 5 dwg

Description

The field of technology.

The claimed solution relates to lighting technology, namely to LED lamps powered directly from the AC mains.

Known level.

It is known that LED lamps need to remove heat from drivers and, especially, from LEDs, since approximately 50% of the electrical energy supplying LEDs is converted into heat, which causes the LEDs to overheat and fail if heat is not provided for the environment. ... This is especially true for lamps with a power of more than 7-8 watts. For such lamps, special radiators are usually created through which heat goes into space. These radiators significantly complicate the design of lamps and increase their dimensions. At the same time, in a typical lamp design, the space under the bulb is filled with air having a low thermal conductivity of ~ 0.02 W / K⋅m and the material of the bulb itself - polycarbonate (0.3 W / K⋅m) is also actually a thermal insulator, therefore the heat coming from the LEDs in the direction of light emission is practically blocked.

Known LED lamp containing a metal radiator in the form of a multifaceted prism, on the edges of which are printed circuit boards, a light diffuser covering the said prism, end caps equipped with through holes for convection heat transfer, while one of the caps is equipped with a means of connecting to the power supply network (WO 2015 / 129419 A1, IPC F21V 29/50, published 03.09.2015).

The disadvantage of the analogue is the need for an overall radiator, limiting the increase in the light power of the lamp due to problems with the removal of excess thermal energy emitted by LEDs.

Known LED lamp containing a light diffuser in the form of a piece of glass pipe of circular cross-section, a printed circuit board, on the mounting surface of which a plurality of LEDs are mounted, and which by the reverse side of the board is pressed by spring holders to the inner surface of the light diffuser for heat exchange, end caps, one of which is equipped means for connecting to the power supply network (US 2016084482 A1, IPC F21V 19/00, published 03.24.2016).

The radially curved board of the specified analogue is placed on the segmented inner surface of the glass diffuser so that the LED radiation is directed to the opposite inner wall of the glass diffuser, which limits the radiation angle, while the excess heat is removed from the LEDs from the back side of the board through two interfaces: from the LEDs to the board and from the board to the body of the glass diffuser, both of which include an air gap.

Known frameless LED lamp containing a sealed light diffuser in the form of a glass tube of circular cross-section, a number of longitudinally fixed on a metal armature filament light sources, enclosed in a silicone shell, which is installed in thermal contact with the inner surface of the light diffuser. To improve heat dissipation, a heat-dissipating paste is placed between the silicone shell and the glass body, filling the inevitable air gap, while the cavity of the diffuser is filled with a heat-conducting gas (US 20190331302, IPC F21K 9/232, published on October 31, 2019).

The disadvantage of the known analogue is the complexity of the lamp design and the difficulty of removing excess heat from light sources through several interfaces: from LEDs to silicone, from silicone to a glass body through a gap filled with heat-conducting paste, or from silicone through a heat-conducting gas to a glass body, therefore the power of such lamps does not exceed 7 ... 10 W.

The technical result of the claimed design is to simplify the design, improve heat dissipation and reduce the labor intensity of manufacturing high-power lamps for general use, resistant to external influences> IP65, and with a minimum cost and labor intensity.

Disclosure of the utility model.

The claimed solution is characterized by a combination of the following features: a radiator housing made in the form of a hollow cylinder, two covers connected to the ends of the cylinder, one of which ends with a base for connecting to an electrical network, and the second has a series of holes along the outer diameter for filling with transparent material. A flat flexible printed circuit board with LEDs installed on it in one part and a driver mounted on the other part of the board is deformed in such a way that the LEDs are on the outside of the cylinder formed by the printed circuit board, and part of the board with the driver components is wrapped inside the cylinder. On the ends of the cylinder, covers are put on from both sides, which are securely fastened to the printed circuit board with the help of glue embedded in the slots of the covers, the network leads coming from the driver are connected to a base that is screwed onto one of the covers. Next, the lamp is inserted into a mandrel, which forms a body-radiator and a transparent (matte) material is poured through the top cover, it can be optical polyurethane or others, which fills the space between the inner cylindrical surface of the tooling, a printed circuit board with LEDs so that above the emitting the surface of the LEDs formed a layer of polyurethane with a thickness of 0.2 ... 0.5 mm. This layer is determined by the inner diameter of the mandrel, and its centering is guaranteed by special SMT components, which are installed on the boards in a circle at a certain distance, and have a height greater than the height of the LEDs by the amount of the required polyurethane layer thickness above the LEDs. After the polyurethane has cured, the lamp is ready for use. To speed up the curing process, the lamp can be connected to the network and, accordingly, be heated to a certain temperature. With a LED height of 0.7 mm and a polyurethane layer above them of ~ 0.4 mm, a layer with a thickness of 1.1 mm is formed above the PCB mounting surface. To improve heat dissipation, this thickness can be reduced either by reducing the diameter of the tool holder in the spaces between the LEDs, or by deforming the PCB in the spaces between the LEDs. The first option is simpler and more reliable in execution. Thus, it is possible to manufacture lamps with a power of up to 100 W or more, it all depends on the area of the radiator body, which is both a diffuser and an insulator. In general, you can be guided by the size of the area 7 ... 12 cm ² per watt of lamp power. At high lamp power, holes are made in both plastic covers and, thus, the inner surface of the printed circuit board, which is made of soft aluminum, is also included in the LED cooling system, which significantly improves the efficiency of heat removal from the case.

Such a lamp design is suitable for installation on outdoor lighting masts, in this case, when replacing a lamp in an already worked illuminator housing, you can install LEDs only on a part of the PCB area, for example, at an angle of 90 °, since the reflectivity of old illuminators is poor and it makes sense saving on LEDs. In this case, the cover with the base consists of two parts, which allow orienting the luminous flux to the road after screwing the lamp into the socket.

The figures show:

fig. 1. - three-dimensional image of a variant of the lamp in analysis;

fig. 2 is a side view of the lamp shown in fig. 1, assembled;

Fig. 3 is a scan of the version of the printed circuit board of the lamp shown in Fig. 1;

in fig. 4 and 5 are cross-sectional views of the configured printed circuit board into the body of the heat sink housing.

Positions in the figures indicate:

1 - the body of the light housing-radiator,

2 - scan of the flexible printed circuit board,

3 - a lot of LEDs,

4 - configured flexible printed circuit board,

5 - secondary power supply,

6 - the first end cap of the radiator housing,

7 - means for connecting to the power supply network (base),

8 - opposed plug of the radiator housing,

9 - edge of the flexible printed circuit board,

10 - protrusion on the printed circuit board.

In fig. 1 shows a disassembled lamp, and Fig. 2 is a side view of a lamp assembly. In fig. 3 shows a scan of a flexible printed circuit board 2, on the mounting side of which a plurality of LEDs 3 and power supply components are mounted 5. All components are installed on SMT machines in one installation, for this we use a sequential power supply that does not have external components (filters, etc.) ) for installation in holes.

The reamer (Fig. 3) of the flexible printed circuit board 2 is configured by bending into a tube with the mounting side outward and installed in the injection mold, and a transparent compound in the liquid phase is introduced into the gap between the inner surface of the injection mold, the emitting surface of the LEDs and the mounting surface of the board, after curing LEDs are immersed in a transparent compound, and the PCB mounting surface is bonded to it by adhesion forces. Thus, the transparent compound performs several functions: the formation of a lamp body, a cooling radiator, a diffuser and a dielectric that insulates live parts from contact.

For pouring, a transparent compound can be used that has high light transmittance and temperature resistance, withstands thermal contact with the LED body without destruction, and does not poison the LED. Of a number of known transparent resins (acrylic, epoxy, polyurethane), the most suitable are compounds based on polyurethane resin, which have a thermal conductivity that, at a distance of less than 1 mm from the light-emitting surface of the LED and to the outer surface of the diffuser, provides sufficient heat exchange with atmospheric air.

Also, the thermal conductivity and efficiency of such a heat sink housing is very good due to the good adhesion of polyurethane and the absence of air between the PCB and the environment.

End caps 6 and 8 can be glued. The opposed plug 8 can be transparent, and then, if there are 2 bends in the configured flexible printed circuit board with installed LEDs, the lamp will provide a full illumination angle. Through-holes (not shown in the drawings) in the end caps provide efficient convection cooling of the FPC backside.

The LED lamp has a point radiation, which is not very good for indoor lighting, but this effect can be reduced by installing LEDs with a small pitch or filling the gap with a compound with added phosphor particles or a diffuser, which at the same time will improve heat transfer from the LEDs to the external heat exchange surface.

For effective cooling, it is advisable to maintain the temperature of the board and the diffuser at the level of 70-75 ° C, then there is radiant heat radiation together with convection. When using efficient LEDs (> 200 lm / W), the real luminous flux efficiency will be ~ 160-170 lm / W (losses in the glass ~ 5%, losses when the LEDs are heated to 85 ° C (crystal) ~ 10%). Then, with a power of 30 W on LEDs, the luminous flux can reach 5000 lm. The overall efficiency of the lamp will be lower by the value of the driver efficiency (~ 0.89) and will be about 147 lm / W.

Claims (12)

1. A die-cast radiator LED lamp containing: a radiator housing made in the form of a hollow cylindrical body made of optically transparent material; the only flexible aluminum PCB with LEDs and LED driver mounted on the mounting side; end caps, at least one of which is provided with means for connection to the power supply network, characterized in that the flexible printed circuit board is configured in the form of a cylinder, with the mounting side outward, and part of the board with the driver is bent inside the cylinder, at the same time, the mounting side of the printed circuit board and the LEDs are embedded in the body of the transparent body-heat sink, forming a single whole, and the mounting surface of the printed circuit board is connected to it by adhesion forces. 2. The LED lamp of claim. 1, characterized in that the part of the mounting surface of the printed circuit board located between the LEDs and the emitting surface of the LEDs are at the same level. 3. The LED lamp of claim. 1, characterized in that the driver is sequential. 4. The LED lamp according to claim 1, characterized in that the end caps are provided with through holes for convection heat removal. 5. The LED lamp according to claim 2, in which the thickness of the optically transparent material of the body-heat sink is approximately the same both on the surface of the LEDs and on the surface of the printed circuit board. 6. The LED lamp of claim. 1, in which the LEDs are located on a part of the perimeter of the printed circuit board surface, for example, at an angle of 90 °, and to orient the LEDs in the desired direction after screwing the cap, the cap with the cap is made of two parts with a ratchet.

Images