RU2595258C1 - Led lamp with forced cooling system - Google Patents

Abstract

FIELD: lighting.

SUBSTANCE: invention relates to semiconductor light engineering, in particular to light-emitting diode (LED) lamps with high-power LEDs, requiring forced cooling, and with high degree of protection against impact of environment. Led lamp comprises a light-transmitting bulb filled with gaseous heat carrier, surrounding LED module in form of convex polyhedron made from conductive material with LEDs installed in faces and with longitudinal channel for circulation of coolant flow cooling its wall, connected through a throat at one end of outlet opening with inner volume of bulb, and through inlet coupled with axial electric fan arranged in flow-guiding heat insulating pipe. Said pipe is installed coaxially in hollow housing of lamp and creates together with its heat transmitting walls an annular cavity, and connected by slits for flow of coolant from internal volume of bulb, to form a recuperative heat exchanger of closed system of forced cooling. Outlet of neck of channel of LED module is screened on front by convex coolant flow spreader, installed inside or in axial hole of bulb or in form of convex wall of bulb, to form an annular clearance with neck for circular redistribution of coolant at a tangent to wall of bulb and outflow into cavity of recuperative heat exchanger. To increase heat exchange, inner walls of channel of LED module and walls of housing rough and/or ribbed, and outer walls of housing with cooling ribs or plated. Converter of network and light control means can be assembled inside housing, near cavity of heat exchanger or extend from lamp.

EFFECT: improved operating performances, higher power, improved thermal and lighting parameters and reduced dimensions.

9 cl, 3 dwg

Description

The present invention relates to semiconductor lighting technology, in particular to LED lamps with high-power LEDs that require cooling during operation and at the same time have a high degree of protection against environmental influences, with an electronic power supply converter and / or light control devices built into the lamp fixture or removed from it .

Similar lamps with a power of up to 200 W and more can be used in general industrial, household and special lighting equipment to replace high-power incandescent lamps, compact fluorescent lamps / CFL /, high-pressure discharge lamps / GRL VD /, including DRL, DRI, DNaT small and medium power with bulky ballast control / EMPRA, EPRA / having poor quality of light and environmental parameters / contain mercury / requiring expensive disposal.

At the same time, there are known problems of cooling high-power LEDs / LEDs / lamps with both flat and bulky LED modules / 1 /, significantly affecting their lighting characteristics and service life, as well as the possibility of minimizing dimensions and reducing structural materials.

In this regard, attempts are being made to use compact single-phase heat exchangers in LED lamps built on convective cooling with a moving coolant in open and closed systems, discussed, for example, in / 2 /.

It is known to use a closed system of forced cooling of the anode assembly of a gas discharge xenon lamp using a recuperative heat exchanger with an axial electric fan in sealed floodlights for special purposes / 3, 4 /.

Partially, the problem of cooling high-power lamps was solved by Uniel / China /, which developed LED lamps of the Venturo / 5, 6 series with a power of 30-100 W with a flat LED module and a forced-cooling electric fan installed near the LED holder, assembled together with the mains converter in hollow barrel-shaped lamp housing with ventilation ducts on its side walls for the intake and discharge of cooling air from the environment.

The disadvantages of the prototype are associated with difficulties in increasing the lamp power due to the low cooling efficiency of a flat SD module and with a low degree of protection of structural elements located in the housing, including the electric fan, current supply devices and the converter from environmental influences.

This circumstance limits the operation of the lamp, for example, in open space in conditions of high humidity, salt fog, etc.

In addition, in lamps with a flat module, as is known / 1 /, it is impossible to use a large number of high-power LEDs without increasing the area of the LED module, i.e. dimensions of the lamp. For this reason, for example, a lamp of the aforementioned series with a power of 100 W of type LED-M88-100 E27 has dimensions of ⌀98 × 187 mm, significantly exceeding the dimensions of the GD VD, comparable in luminous flux.

The aim of the invention is to improve performance by increasing the degree of protection of the lamp from environmental influences while increasing power, improving thermal and lighting parameters and minimizing dimensions.

This goal is achieved in that in an LED lamp with a forced cooling system containing a light-transmitting flask filled with an optically transparent coolant, an LED / LED / module with a holder separating the flask from the hollow body, an electric fan and current supply elements with a standard base, the specified LED module is made in the form of a convex polyhedron of heat-conducting material with LEDs assembled on the faces and with a longitudinal channel for circulation of the coolant flow connected at one end of through the mouth of the outlet with the inner volume of the flask, and through the inlet at the opposite end of the channel, paired with an axial electric fan assembled in a coolant guide pipe made of heat-insulating material, mounted coaxially in a hollow body with heat transfer walls and together creating an annular cavity connected to the inner volume flasks with slots for the flow of coolant flow, performed on the periphery of the annular holder of the SD module, with the formation of a regenerative heat transfer nnika of the closed system of forced cooling.

The goal is also achieved by the fact that the outlet opening of the neck of the longitudinal channel of the SD module is shielded by a frontally convex coolant flow divider mounted on the neck brackets with the formation of an annular gap for the circular redistribution of the indicated coolant tangentially to the walls of the flask and its expiration through the slots of the ring holder of the SD module in recuperative heat exchanger annular cavity.

The goal is achieved by the fact that the outlet opening of the neck of the longitudinal channel of the SD module is shielded frontally convex, with needle cooling elements on the back side, a coolant flow divider forming an annular gap with the mentioned neck for circular redistribution of the coolant flow tangentially to the flask walls and installed hermetically in the axial hole of this flask with the rear part protruding from it with needle elements into the surrounding space for convective cooling.

Achieving the goal is also facilitated by the fact that the outlet opening of the neck of the longitudinal channel of the SD module is shielded by the frontally convex part of the flask forming a coolant flow divider with its circular redistribution into the annular gap formed by it and its outflow tangentially to the flask walls and through the slits of the ring holder into the annular cavity recuperative heat exchanger.

The problem is also solved by the fact that the inner walls of the longitudinal channel for the flow of the coolant flow are made rough and / or with longitudinal cooling fins of the SD module for turbulence of the boundary layer of the flow and increase the heat transfer surface.

The problem is also solved by the fact that the heat-transferring internal walls of the hollow body are made rough and / or with longitudinal cooling fins and finned on the outer surface for turbulence of the boundary layer and increase of the heat exchange surface with the coolant flow and with the environment, respectively.

The goal is also achieved by the fact that the LED module is made with reflective faces and short-wave radiation LEDs mounted on them, mainly deep blue or blue radiation, and integrated into the walls of the flask or they are covered with a phosphor layer selected from the group of yttrium-aluminum garnet activated by cerium / YAG: Ce ⁺³ /, which converts the radiation of LEDs into white light and scatters it.

Achieving the goal is also facilitated by the use of a gaseous refrigerant selected from the group of air, nitrogen or inert gases, with filling the internal volume of the lamp under normal pressure at a temperature of 290-300 K.

The task is also facilitated by the fact that an electronic converter of the mains supply and / or light control devices are installed in the hollow lamp housing, adjacent to the annular cavity of the regenerative heat exchanger, with the possibility of cooling the heat-stressed components by the coolant stream and connecting the current supply elements to the SD module, electric fan, and standard the cap.

Preferred embodiments of LED lamps with a closed forced cooling system are shown in the drawings.

FIG. 1 - LED lamp with a volumetric LED module with a longitudinal channel and a recuperative heat exchanger, a coolant flow divider installed inside the bulb. Side view, partially in section.

FIG. 2 - LED lamp with a compact volumetric LED module with a longitudinal channel, a regenerative heat exchanger and a coolant flow divider protruding from the bulb. Side view, partially in section.

FIG. 3 - LED lamp with a volumetric LED module with a longitudinal channel mounted in a bulb with a wall in the form of a coolant flow divider.

Shown in FIG. 1, an LED lamp with a closed forced cooling system contains a light-transmitting glass or optical polycarbonate bulb 1 in the form of a truncated ellipsoid of revolution surrounding an extended volumetric LED module 2 mounted on its ring-shaped holder 3, which is connected to its end part. The holder 3 separates the inner volume of the bulb from the hollow body 4 of the lamp, hermetically connected to it through an annular seal.

At the same time, the flask 1 can be directly connected to the housing 4, and the supporting LED module 2, the ring holder is mechanically and in thermal contact fixed on the inner surface of the housing.

The SD module 2 is made of a heat-conducting material, mainly based on aluminum, in the form of a hollow, i.e. convex, polyhedron, in particular, in the form of an extended truncated pyramid with reflective, for example, mirrored outer faces, the inner cavity of which forms a longitudinal channel 5 with a developed surface of the walls to circulate the coolant flow and provide heat transfer. A gaseous refrigerant was used, selected from the group of air, nitrogen or inert gases, with the internal volume of the lamp being filled under normal pressure at a temperature of 290-300 K. The gases should be drained, free of moisture and other impurities interacting with the phosphor, protective compounds and other structural elements.

On the long edges of the LED module 2, short lines with LEDs or individual LEDs 6 are assembled in thermal contact, for example, Cree XLamp XT-E, XP-G, XM-L, connected in series or in parallel to each other by printed or wall mounted elements current lead.

The longitudinal channel 5 of the SD module is connected at one end / upper base / of the truncated pyramid through an outlet with a neck 7 with an inner volume of 8 flasks, and the inlet / lower base of the pyramid / at the opposite end of the longitudinal channel is mated through an axial hole of the ring holder 3 with an axial electric fan 9 installed in the guide coolant pipe 10 made of heat-insulating material.

The pipe 10 is coaxially mounted in a hollow body 4 with rough and / or finned inner walls and together with them creates an annular cavity 11 connected to the inner volume of the flask 8 by slots 12 for the coolant to flow out of it, made on the periphery of the annular holder 3. The annular cavity 11, formed by the heat-transferring walls of the hollow body 4 and the coolant guide pipe 10, constitutes the main link of the regenerative heat exchanger of the closed system of forced cooling of the lamp as a result of The electric fan 9 circulates the coolant in the longitudinal channel 5 of the SD module, in the volume of 8 flasks, in the annular cavity 11 of the hollow body 4 and the pipe 10 / shown by arrows /.

The outlet opening 7 of the longitudinal channel 5 of the SD module is shielded by a frontally convex divider 13 of the coolant flow mounted on the brackets 14 of the neck with the formation of an annular gap with it for circular redistribution / shown by arrows / coming out of the channel heated by convective heat exchange on the walls of the SD module coolant flow. The diffuser 13 is made of heat-conducting material and partially reduces the temperature of the coolant flow, dissipating heat in the flask, and directs the flow tangentially to the walls of the flask to flow through slots 12 in the ring holder 3 into the annular cavity 11 of the regenerative heat exchanger for the final cooling cycle.

The cooling efficiency of the coolant in the recuperative heat exchanger is increased by performing longitudinal ribs 15 on the walls of the hollow body 4 from the inside and / or by making them rough to turbulent the boundary layer of the flow and increase the heat exchange surface, also performing them finned on the outer surface, increasing heat exchange with the environment. The efficiency of the heat exchanger can also be improved by lengthening the heat-insulating electric fan of the pipe 10, which contributes to the lengthening of the annular cavity 11, and the use of a fan of high power.

In turn, the inner walls of the longitudinal channel 5 of the SD module 2 were cooled with a developed wall surface also due to roughnesses and / or the manufacture of longitudinal cooling fins 16, mainly of a triangular section, for turbulence of the flow boundary layer and increase of the heat exchange surface, contributing to an increase in heat transfer of the pyramid faces carrying LEDs 6, with a coolant stream. According to / 2, p. 217 / production of roughnesses by machining the inner surface of the channel for the coolant flow increases the heat transfer to 60-80%, although the friction resistance increases only by 10%.

In addition to cooling the LED module, a power supply converter 17 and / or light control devices collected in a zone adjacent to the annular cavity 11 of the regenerative heat exchanger can be integrated into the lamp housing with the ability to cool the heat-carrying electronic components, for example, electrolytic capacitors or a dimmer, and also means for connecting current supply elements of the SD module and the electric fan to the lamp base 18, mounted through an annular insulator 19 on the end of the hollow body 4.

The second embodiment of the LED lamp with a closed forced cooling system is shown in FIG. 2.

Here, the LED module is made in the form of a regular convex polyhedron, in particular, a truncated icosahedron 20 made of heat-conducting material with mirrored faces 21 on which powerful LEDs 22 or mini-modules with similar LEDs of the Cree XLamp XT-E AP series from 1-3 are installed Tue The SD module 20 is made with a longitudinal channel 23 in the form of a nozzle of a subsonic outflow of a coolant flow organized by an axial fan assembly 24 mounted in a heat-insulating pipe mated to a nozzle inlet nozzle directing the coolant flow from an annular cavity 26 of a regenerative heat exchanger similar to that described for a lamp design on FIG. one.

The outlet of the channel 23 in the form of a nozzle with a neck 27 is shielded by a frontally convex coolant flow divider 28 made of a heat-conducting material with needle-shaped cooling elements 29 on the rear side, forming an annular gap with the neck 27 of the SD module for the circular redistribution of the coolant in the bulb tangentially to it the wall / shown by arrows / and its outflow through slots 30 made on the periphery of the annular holder, which is the flange of the SD module, into the annular cavity 26 of the regenerative heat a bar with a finned heat transfer wall of the hollow body 31.

The divider 28 is hermetically mounted on the wall of the axial opening of the flask 32 with the back portion protruding from it with needle elements 29 into the convective cooling space surrounding the lamp, thereby reducing the temperature of the coolant entering the inner walls of the flask.

This is especially important for the embodiment of the LED lamp, as shown in FIG. 2, with the distant phosphor 33, i.e. integrated into the walls or deposited on the walls of the flask, for example, in a mixture with optically transparent silicone, or a protected silicone layer that converts part of the short-wave radiation of the LEDs into a white glow and scatters it. The phosphor is mainly chosen from the group of yttrium-aluminum garnet activated by cerium / YAG: Ce ⁺³ /, whose overheating above 125 degrees leads to a loss of quantum efficiency.

In this case, the high-power LEDs 22 collected on the mirrored faces 21 of the LED module 22 are selected for short-wave radiation, deep blue or blue radiation (~ 450-470 nm) of the aforementioned series.

The heat transfer inner walls of the hollow body 31 forming the recuperative heat exchanger can be made rough in addition to fins, as well as for the first lamp variant to increase the turbulence of the boundary layer of the coolant flow and the area of heat exchange with it. The outer surface of the housing 31 made of aluminum can be anodized to increase heat transfer with the environment by increasing the emissivity from 0.2 to 0.8 / 7 /.

For a lamp with a remote phosphor, dried nitrogen or inert gases must be used as a coolant, eliminating the possibility of phosphor degradation at elevated temperatures due to oxidative processes that contribute to a change in the valence of the activator.

Another embodiment of the LED lamp with a closed forced cooling system shown in FIG. 3, provides for the screening of the outlet of the longitudinal channel with the neck 34 of the SD module 35 with the frontally convex part of the glass flask forming a glass divider 36 of the coolant flow with its circular redistribution along the tangent to the walls of the flask through the annular gap 37 formed by the neck and walls of the divider and its expiration through the slots 38 in the ring holder of the above-mentioned LED module into the annular cavity 39 of the hollow body 40 with heat transfer walls of a regenerative heat exchanger for cooling / lkami /.

This option is advisable to use in lamps with light-transmitting bulbs made of silicate glass, having a thermal conductivity 5 times higher than polycarbonate bulbs / 1 /.

The considered lamp design options provide for the placement and cooling of heat-stressed components of the converter and light controls in the hollow lamp housing / Fig. 1 and 2 / or lamp design without the named elements, i.e. with lamps removed from the fixture / Fig. 3 /, which for high power lamps and a number of applications is preferred.

As an axial electric fan in the used cooling system, small-sized electric fans of the AD0424MS-G70 / ⌀40 × 10 mm / DC power supply with DC 24 V, 0.08 A from Adda Cooler / China / with connection to a power supply converter or to the cap.

The proposed lamp options with a closed forced cooling system significantly improve operational performance by increasing the degree of protection against environmental influences to IP67 according to GOST 14254 when used in protected lampholders, as well as providing opportunities to increase power and improve lighting parameters with optimization of thermal conditions and minimizing dimensions .

Literature.

1. V.V. Sysun. "Status of development of compact LED emitters and lamps with a remote phosphor." J-semiconductor lighting technology. 2013, No.6, p. 39-48.

2. A.A. Zhukauskas. "Convective transport in heat exchangers." M .: Publishing. The science. 1982, p. 425-439.

3. V.V. Sysun et al. Auth. St. No. 1348606 A1, bull. No 40 on 10/30/1987

4. Yu.G. Basov and others. "Special lighting." Minsk, "Publishing center of BSU". 2008, p. 209-210.

5. Wl "Market lighting". 2014, No. 5/24 /, p. 72-73. /http://www.uniel/ru/. "New Uniel: Venturo 30-100W high power LED bulbs.

6. S. Nikiforov, A. Arkhipov. "Remix in the lighting industry." J-semiconductor lighting technology. 2014, No. 5, p. 8-15.

7. A. Motoya et al. "Thermal management of LED lamps." J-semiconductor lighting technology. 2011, No. 4, p. 45.

Claims (9)

1. LED lamp with forced cooling system, containing a light-transmitting bulb filled with an optically transparent coolant, an LED / LED / module with a holder that separates the bulb from the hollow body, an electric fan and current supply elements with a standard base, characterized in that the LED module is made in the form convex polyhedron of heat-conducting material with LEDs assembled on the faces and with a longitudinal channel for circulation of the coolant flow, connected at one end through the mouth of the outlet a hole with the inner volume of the bulb, and through the inlet at the opposite end of the channel, paired with an axial fan, assembled in a coolant guide pipe made of heat-insulating material, mounted coaxially in a hollow body with heat transfer walls and together creating an annular cavity connected to the inner volume of the bulb by slots for the flow of the coolant, performed on the periphery of the annular holder of the SD module, with the formation of a regenerative heat exchanger of a closed system at forced cooling. 2. The LED lamp according to claim 1, characterized in that the outlet opening of the neck of the longitudinal channel of the SD module is shielded by a frontally convex coolant flow divider mounted on the neck brackets with the formation of an annular gap for the circular redistribution of the indicated coolant tangentially to the flask walls and its expiration through slots of the annular holder of the SD module into the annular cavity of the regenerative heat exchanger. 3. The LED lamp according to claim 1, characterized in that the outlet opening of the neck of the longitudinal channel of the SD module is shielded frontally convex, with needle cooling elements on the back side, a coolant flow divider forming an annular gap with the said neck for circular redistribution of the coolant flow along the tangent on the walls of the flask and installed tightly in the axial hole of this flask with the back part protruding from it with needle elements into the surrounding space for convective cooling excitement. 4. The LED lamp according to claim 1, characterized in that the outlet opening of the neck of the longitudinal channel of the SD module is shielded by the frontally convex part of the bulb forming a coolant flow divider with circular redistribution of it into the ring gap formed by it and its outflow tangentially to the bulb walls and through slits of the annular holder into the annular cavity of the regenerative heat exchanger. 5. The LED lamp according to claim 1, characterized in that the inner walls of the longitudinal channel for the flow of the coolant stream are made rough and / or with longitudinal cooling fins of the SD module for turbulence of the boundary layer of the stream and increase the heat transfer surface. 6. The LED lamp according to claim 1, characterized in that the heat-transferring internal walls of the hollow body are made rough and / or with longitudinal cooling fins and finned on the outer surface to turbulence the boundary layer and increase the heat exchange surface with the coolant flow and with the environment, respectively. 7. The LED lamp according to claim 1, characterized in that the LED module is made with reflective faces and light-emitting diodes of short-wave radiation, mainly deep blue or blue radiation, mounted on them, and integrated into the walls of the bulb or covered with a layer of a phosphor selected from the yttrium group -aluminium garnet activated by cerium / YAG: Ce ⁺³ /, which converts the radiation of LEDs into white light and scatters it. 8. The LED lamp according to claim 1, characterized in that a gaseous refrigerant is used selected from the group of air, nitrogen or inert gases, with filling the internal volume of the lamp under normal pressure at a temperature of 290-300 K. 9. The LED lamp according to claim 1, characterized in that an electronic converter of the power supply network and / or light control devices are installed in the hollow lamp housing adjacent to the annular cavity of the regenerative heat exchanger, with the possibility of cooling the heat-stressed components by the coolant stream and connecting the current supply elements to the SD- module, electric fan and standard base.

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