KR101270257B1 - Heat pipe type heat sink for tube shape led lamp and tube shape led lamp using the same - Google Patents

Abstract

The present invention relates to a heat pipe type heat sink for a tube type LED lighting lamp and a tube type LED lighting lamp using the same, and the present invention relates to an LED mounting portion having a target LED mounting surface, and a length extending direction of the LED mounting portion. Accordingly, an upwardly extending portion protruding from both opposite ends of the LED mounting surface and having a locking jaw on the outside, and an upwardly inclined portion extending from an inner lower portion of the upwardly extending portion to an inclined or curved gradient to form a corner at the center, and an LED mounting portion And an enclosed space formed by the upwardly inclined portion and integrally formed: a heat pipe type heat sink for a tubular LED lighting lamp in which a refrigerant is filled in the enclosed space under atmospheric pressure or reduced pressure, and a tubular LED lighting lamp using the same. According to the invention, since the outer pipe of the heat pipe itself functions as a direct heat sink, excellent heat transfer rate and heat dissipation Ratio, and therefore, it is possible to minimize the degradation of optical output characteristics, shorten the lifespan and efficiency of the LED due to the heat generated from the driving of the LED, and also have high economical efficiency and durability due to the simple structure, so that it is effectively applied to the tube type LED lighting lamp. Can be.

Description

HEAT PIPE TYPE HEAT SINK FOR TUBE SHAPE LED LAMP AND TUBE SHAPE LED LAMP USING THE SAME}

The present invention relates to a heat pipe type heat sink for a tube type light emitting diode (LED) lighting lamp and a tube type LED lighting lamp using the same, and more particularly, a tube type LED lighting lamp having a long length such as a conventional fluorescent lamp. The present invention relates to a heat pipe type heat sink for use and a tube type LED lighting lamp using the same, wherein a new type of heat pipe type heat in which an outer shell of a heat pipe itself that transfers heat by using latent heat of evaporation according to a phase change of a refrigerant functions as a heat sink. The sink exhibits excellent heat transfer rate and heat dissipation efficiency compared to the conventional structure in which the LED transmits heat to the heat sink through the heat pipe and then dissipates it through the heat sink. Not only can reduce degradation, reduce lifespan and reduce efficiency, Its high cost and durability due to its simple structure make it effective for tube-type LED lighting lamps.

LED (Light Emitting Diode) has high light conversion efficiency, relatively low power consumption, can be expanded and installed, semi-permanent, and no preheating, so the response speed is fast, the lighting circuit is relatively simple, and the gas and filament for discharge Since it is not used, it has the advantages of high impact resistance, safety, low environmental pollution, high repetitive pulse operation, less optic nerve fatigue, and full color implementation. As a trend, according to the commercialization of high power and high efficiency LEDs, its use and usage are also rapidly expanding, and especially as tube type LED lighting lamps such as fluorescent lamps have been developed, they are actively being used in offices, factories or homes. have.

The tube-type LED lighting lamp adopts a method of dramatically increasing the brightness or luminance of the LED lighting lamp by using a structure in which a plurality of LED elements are arranged in the same plane in a high density in series and / or in parallel. As the integrated density of the LED increases, the heat generated by the driving also increases significantly. Therefore, a problem arises that the optical output characteristic of the LED decreases, the lifespan decreases, and the efficiency decreases.

Therefore, the retention of sufficient heat dissipation in all LED lighting lamps, including tubular, is essential to ensure that the predetermined optical properties of the high power and high efficiency LEDs are kept constant.

Conventionally, in order to solve the heat dissipation problem of the LED lighting lamp as described above, the heat sink and / or heat spreader having a large surface area made of metal such as copper or aluminum having excellent thermal conductivity is used in semiconductor parts such as LEDs. The method of dissipating heat to the air is widely applied, and in recent years, the heat sink is operated using a heat pipe having excellent heat transfer characteristics using latent heat of evaporation caused by a phase change of a refrigerant (ie, working fluid). The application of heat transfer and dissipation through heat sinks is also rapidly expanding.

As a typical example of a conventional tubular LED lighting lamp and a heat sink applied thereto, FIG. 4A disclosed in Korean Patent No. 0990424 (published on May 03, 2010 / October 21, 2010) proposed by the present applicant And tubular LED lighting lamps 10 and heat sinks 20 as shown in FIG. 4B.

The illustrated typical heat sink 20 for a tubular LED lighting lamp has a long concave portion on a point surface and is formed in an overall strip shape in which a plurality of heat dissipation fins 21 are formed on the back side along a length direction, which is an LED and The function as a base frame on which a circuit board is mounted is also performed.

Long grooves for inserting both open ends of the tubular cover 40, one side of which is transparent or translucent one side open along its length, on both outer surfaces of the conventional typical tubular LED lighting lamp described above. (Not shown) and long grooves (not shown) for inserting both side ends of the circuit board 31 on which the LEDs 30 are mounted along the longitudinal direction thereof.

In the conventional LED lighting lamp 10 using the conventional heat sink 20 for the tubular LED lighting lamp described above, a thermal conductive resin 22 is filled between the circuit board 31 and the heat sink 20. In this structure, the terminals 23 are formed at both ends, and the lens 32 is formed on the LED 30 described above.

However, the heat sink 20 for the conventional typical tubular LED lighting lamp as described above only follows the general heat sink form in which the heat dissipation fin 21 is formed on the heat dissipation side without using a heat pipe, thereby sufficiently satisfying the heat dissipation efficiency. In addition, there is a problem that the driving heat from the LED is too large in the heat conduction resistance at the interface between dissimilar materials during the sequential heat conduction process to the heat sink 20 through the circuit board 31 and the heat conductive resin 22. there was.

As another typical example of a conventional tubular LED lighting lamp and a heat sink applied thereto, it is also disclosed in Korean Patent No. 0967569 (registered on September 30, 2009 / 2010.06.25) proposed by the present applicant. The tubular LED lighting lamp 10a and the heat sink 20 as shown to FIG. 5A and 5B are mentioned.

The heat sink 20 for the conventional typical tubular LED lighting lamp shown is also substantially the same as the above-described example, but for the purpose of assembling convenience, the heat sink 20 is separated into two pieces of left and right symmetry. And as a structure for fixing this using the fixing means 24, the heat radiation fins 21 are formed only on the outer end of each heat sink 20.

However, such a structure also has a problem inevitably facing the same problem as shown in Figures 4a and 4b.

Meanwhile, the conventional general heat pipe 50 and its operation principle are shown in FIG. 6, and the structure of the conventional general heat pipe 50 is the pipe 51 and the sintered-metal wick 52. ) And a refrigerant.

The pipe 51 is a long cylindrical shape, the inside is sealed under reduced pressure, and the metal sintered wick 52 is a metal powder sintered body in which micropores exhibiting capillary action are present. It is formed on the inner circumferential surface of the).

The heat transfer mechanism of the heat pipe 50 having the above-described configuration, when the operating heat (H) is transferred to the heat absorbing portion 55 thermally coupled to the LED heat source (not shown), the heat absorbing portion 55 due to this operating heat The refrigerant located in the metal sintering wick 52 absorbs the operating heat corresponding to the latent heat of evaporation while the phase changes into the gas phase, and the vaporized refrigerant is in the direction of the arrow shown in FIG. 6 due to the internal pressure difference of the pipe 51. The vaporized refrigerant is moved toward the heat generating unit 53 through the vapor flow passage 54, and the moved vaporized refrigerant transfers the operating heat H to a heat sink (not shown) that is thermally coupled to the heat generating unit 53. At the same time, the condensation is changed back to the liquid phase, and the working liquid is transferred while repeating the process of moving the liquid refrigerant toward the endothermic portion 55 again by capillary action.

As described above, a heat pipe having a metal sinter wick has a circular cross section and a mandrel having a smaller diameter is inserted into a pipe having an end forming portion having a reduced diameter at a lower end thereof. After heating and sintering the space metal powder between the insertion mandrel and the inner wall of the pipe, the insertion mandrel is removed, the upper end of the pipe is welded and sealed, and an appropriate refrigerant is introduced through the end forming part. It is usually prepared by injecting pressure-reduced sealing after injection, or by applying a binder to the inner circumferential surface of a heat pipe having a circular cross section, spraying metal powder thereon, sintering and sealing under reduced pressure after refrigerant injection.

Subsequently, Korean Patent No. 0756897 (registered on September 3, 2007) discloses a conventional type LED lighting lamp (not shown) using the heat pipe 50 and the heat sink 26 as shown in FIG. I'm proposing.

In the illustrated LED lighting lamp, a circuit board 31 on which a plurality of LEDs 30 are mounted is located in a space formed of a heat dissipation cover 20 and a floodlight cover 40, and the mounting portions of the plurality of LEDs 30 are described above. The heat pipe 50 is installed vertically upward from each rear, and the vertical end of the heat pipe 50 is thermally connected to the body 21a of the heat sink 26 having the heat dissipation fins 21. to be.

However, this conventional heat dissipation structure has a problem that the heat dissipation efficiency is higher than that of using only the heat sink, but the structure is somewhat complicated, and therefore, it is not good in terms of structural durability and economy.

In the drawings, reference numerals 25 and 25b denote heat radiating holes.

Accordingly, the development of a heat pipe type heat sink for a tubular LED lighting lamp and a tubular LED lighting lamp using the same have been desired in the art, which overcomes all the problems of the prior art as described above.

Accordingly, a first object of the present invention is to provide a heat pipe type heat sink for a tubular LED lighting lamp of a novel structure exhibiting excellent heat transfer rate and heat dissipation efficiency as the outer shell of the heat pipe itself functions as a heat sink.

A second object of the present invention is to provide a heat pipe type heat sink for a tubular LED lighting lamp having a high thermal conductivity by extrusion rather than injection.

A third object of the present invention is to provide a heat pipe type heat sink for a tubular LED lighting lamp having a high economy and durability due to a simple structure.

A fourth object of the present invention is to provide a heat pipe type heat sink for a tubular LED lighting lamp that can be easily and easily assembled without a separate fixing means of the tubular floodlight cover.

The fifth object of the present invention is the heat pipe type heat for the tube-type LED lighting lamp according to the first to the fourth object described above, which minimizes the concern about deterioration of the optical output characteristic of the LED due to the heat generated by the driving of the LED, shortening the lifespan and deterioration of efficiency. To provide a tubular LED lighting lamp using a sink.

According to one preferred aspect of the present invention for smoothly achieving the first to fourth objects of the present invention, there is provided a light emitting device including: an LED mounting portion having a target LED mounting surface; An upward extension part protruding at both ends of the LED mounting part in a direction opposite to the LED mounting surface along a length extending direction of the LED mounting part, and having a locking step on the outside thereof; An upwardly inclined portion extending from an inner lower portion of the upwardly extending portions of both sides in an upwardly inclined or curved gradient to form an edge at a central portion thereof; A sealed space portion formed by the LED mounting portion and the upwardly inclined portion is integrally formed: A heat pipe type heat sink for a tubular LED lighting lamp in which a refrigerant is filled in the sealed space portion under an atmospheric pressure or a reduced pressure atmosphere is provided.

According to another preferred aspect of the present invention for smoothly achieving the first to fourth objects of the present invention, the tubular LED lighting lamp is formed integrally with the downward projections at both ends along the longitudinal extension direction of the LED mounting portion, respectively. A heat pipe type heat sink is provided.

According to another preferred aspect of the present invention for smoothly achieving the first to fourth objects of the present invention, a heat pipe for a tubular LED lighting lamp in which the inner longitudinal edges of the respective downward protrusions are formed as upward inclined portions. Type heatsinks are provided.

According to another preferred aspect of the present invention for smoothly achieving the first to fourth objects of the present invention, the above-mentioned upward extension portions on both sides are located in the width region of the downward protrusions on both sides, and each of the above-mentioned upward extensions. The locking jaw of the outer side is formed of upper and lower locking jaws, and is formed together with the upward extension portion and the upward inclined portion by forming integrally the extension end of each upward extension portion as an arc-shaped extension portion. A heat pipe type heat sink for a tubular LED lighting lamp that forms a portion is provided.

According to another preferred aspect of the present invention for smoothly achieving the first to fourth objects of the present invention, the sealed space portion is a triangular body or a pentagonal body by the LED mounting portion, the upwardly inclined portion and the upwardly extending portion. A heat pipe type heat sink for a tubular LED lighting lamp is formed.

According to another preferred aspect of the present invention for smoothly achieving the first to fourth objects of the present invention, the annular upward projection extends outwardly opposite to the downward projection, and the annular upward projection and the LED are formed. A heat pipe type heat sink for a tubular LED lighting lamp is provided in which the recess is defined by the lower part of the mounting portion and the upward extension portion.

According to still another preferred aspect of the present invention for smoothly achieving the first to fourth objects of the present invention, a tubular LED lighting lamp having a plurality of heat dissipation fins integrally formed above the inclined portion in the open space portion. A heat pipe type heat sink is provided.

According to another preferred aspect of the present invention for smoothly achieving the first to fourth objects of the present invention, the inner wall of the enclosed space has a sintered-metal wick having a layer thickness of 0.1 to 0.5 mm. Heat pipe type heat sinks for tubular LED lighting lamps are provided.

According to another preferred aspect of the present invention for smoothly achieving the first to fourth objects of the present invention, the tubular LED lighting lamp is acetone, methanol, ethanol, distilled water, ammonia water, or any mixture thereof. A heat pipe type heat sink is provided.

According to a preferred aspect of the present invention for smoothly achieving the fifth object of the present invention, the above-described heat pipe type heat sink for a tube type LED lighting lamp; An insulating layer formed of an anodized film, a ceramic thin film, or a resin thin film laminated on the LED mounting surface of the heat sink; A conductive circuit pattern layer printed on the insulating layer; An LED mounted on the conductive circuit pattern layer; Provided is a tubular LED lighting lamp composed of an annular tube-type floodlight cover having an open end formed in a longitudinal direction with an engaging projection having a locking projection fastened to the locking projection of the heat sink.

delete

According to another preferred aspect of the present invention for smoothly achieving the fifth object of the present invention, the above-mentioned translucent cover is formed of transparent or translucent, or colorless or colored glass or transparent resin which may include an optical dispersion. Tubular LED lighting lamps are provided.

The heat pipe type heat sink for the tubular LED lighting lamp according to the present invention exhibits excellent heat transfer rate and heat dissipation efficiency according to the adoption of a novel structure in which the outer shell of the heat pipe itself functions as a heat sink, and is suitable for extrusion rather than injection. Since it is manufactured by the high thermal conductivity, and the structure is simple, it has high economical efficiency and durability, and the assembly of the tubular floodlight cover can be easily and easily performed without a separate fixing means, and the heat according to the present invention. Tube-type LED lighting lamps using pipe-type heat sinks can reduce the optical output characteristics of LEDs due to heat generated from the LEDs, shorten the lifespan, and reduce the efficiency, as well as high economy and efficiency in manufacturing, installation, and maintenance. It is also lightweight.

1 and 2 are a perspective view and a front view of a heat pipe type heat sink according to the present invention, respectively.
3 is a cross-sectional view showing the structure and heat dissipation flow of a tube type LED lighting lamp to which a heat pipe type heat sink according to the present invention of FIGS. 1 and 2 is applied.
4A and 4B are perspective and partial cross-sectional views, respectively, of a conventional tube type LED lighting lamp.
5A and 5B are partial perspective and partial cross-sectional views, respectively, of another conventional tube type LED lighting lamp.
6 is a partially cutaway perspective explanatory view showing a principle of operation of a conventional general heat pipe.
7 is a cross-sectional view of a conventional LED lighting lamp using a conventional heat pipe.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described in detail with reference to the accompanying drawings.

1 and 2 are respectively referred to as a perspective view and a front view of the heat pipe type heat sink 1 according to the present invention for convenience of description.

The basic structure of the heat pipe type heat sink 1 according to the present invention includes an LED mounting portion 2 having a target LED mounting surface 2a and an extension of the length of the LED mounting portion 2 described above. An upward extension portion 6 protruding from both ends of the LED mounting surface 2a in a direction opposite to the LED mounting surface 2a and having a locking jaw 7a or 7a and 7b on the outside thereof; An upwardly inclined portion 8 extending upwardly inclined or curved from an inner lower portion of the sixth portion to form an edge 8a at the center, and the LED mounting portion 2 and the upwardly inclined portion 8 described above; The sealed space part 9 formed by this is integrally formed: It is the structure by which the refrigerant | coolant 9a is filled in the said sealed space part 9 in a normal pressure or a reduced pressure atmosphere.

Optionally, downward projections 3 are integrally formed at both ends of the LED mounting part 2 along the length-extending direction, thereby facilitating the mounting of the LEDs (see 110 in FIG. 3). It may serve to guide the light toward the front, it may be formed to smooth the front side guide of the LED light by forming the inner longitudinal edge of the downward protrusion 3 as the upward inclined portion (3a).

In addition, in the present invention, non-limiting optional matters, the above-described upward extensions 6 on both sides are narrowly positioned in the width region of the downward protrusions 3 on both sides, and the respective upward extensions 6 are described above. The outer locking jaws are formed into upper and lower locking jaws 7a and 7b, and the extension ends of each of the upwardly extending portions 6 are formed into arc-shaped extensions 7 having a substantially "T" shape. It may be integrally formed to form an open space 8b together with the upwardly extending portion 6 and the upwardly inclined portion 8.

In the present invention, as an optional matter, a plurality of heat dissipation fins (not shown) known above the upward inclined portion 8 may be integrally formed in the open space 8b to increase heat dissipation efficiency. Of course.

In the present invention, the overall shape of the enclosed space portion 9 is defined by the LED mounting portion 2 and the upwardly inclined portion 8, or the LED mounting portion 2 and the upwardly inclined portion 8 and upwardly extending. It is formed in the form of a triangular body or pentagonal body formed by the portion 8 is a structure that can be carried out heat through the edge (8a) smoothly.

In addition, in the illustrated example, the annular upward protrusion 4 is formed to extend outwardly opposite to the downward protrusion 3, and the annular upward protrusion 4, the LED mounting portion 2, and the upward extension 6 are formed. Although the annular recess 5 is formed by the lower part of), the form of the recess 5 or the form or the inclination angle of the annular upward protrusion 4 are optional in the present invention.

In the present invention, it is of course also possible to form a sintered-metal wick 9b having a layer thickness of 0.1 to 0.5 mm on the inner wall of the enclosed space 9.

If the thickness of the metal sintered wick 9b layer is less than 0.1 mm, the flow of the refrigerant due to the capillary phenomenon may not be sufficient, and if the thickness exceeds 0.5 mm, it may also adversely affect the flow of the refrigerant. Not desirable

The metal powder for forming the metal sintered wick 9b is copper or aluminum powder, and copper powder is preferable from the viewpoint of high thermal conductivity, and the diameter of the powder is 5 to 400 µm, preferably 20 to 300. Μm, the sintering temperature is 2 to 8 hours in the range of 820 to 1250 ° C., and the formed metal sintering wick 9b includes a plurality of voids therein and the porosity is related to the movement of the refrigerant by capillary action, thus The sintering temperature and time of the metal powder are determined according to the type of metal powder and the desired porosity.

The sintering treatment is terminated to form a metal sinter wick 9b, and one end is sealed, and then the refrigerant 9a is put therein, and the other end is sealed under normal pressure or reduced pressure.

The seal is sealed at both ends with a stopper such as an elastomer having good elasticity and high sealing properties such as butadiene-rubber, natural rubber, silicone, or the like, or by laser spot welding, high frequency welding, or the like. It is possible to use it because it is relatively less likely to release the seal when the inside is decompressed.

In addition, as a kind of said refrigerant | coolant 9a, acetone, methanol, ethanol, distilled water. It is common to use ammonia water, or any mixture thereof, but in rare cases carbon nanotube (CNT) or hexagonal continuous structure of six carbons, graphene, pure carbon ( Activated carbon), copper powder, boron nitride and the like.

3 is a cross-sectional view showing the structure and heat dissipation flow of the tube type LED lighting lamp 100 to which the heat pipe type heat sink 1 according to the present invention of FIGS. 1 and 2 is applied. .

The tube type LED lighting lamp 100 according to the present invention is an anodized film laminated on the heat pipe type heat sink 1 for the tube type LED light lamp described above and the LED mounting surface 2a of the heat sink 1 described above. , An insulating layer 111 formed of a ceramic thin film or a resin thin film, the conductive circuit pattern layer 112 printed on the insulating layer 111, and the conductive circuit pattern layer 112 mounted on the insulating layer 111. The cleavage end (the reference numeral) in which the inward protrusion 121 formed with the LED 110 and the engaging jaw 123 fastened to the engaging jaws 7a or 7a and 7b of the heat sink 1 is formed in the longitudinal direction. And a transparent cover 120 in the form of an annular tube with no grant).

More specifically, the bottom surface of the inwardly projecting portion 121 of the floodlight cover 120 abuts against the tip portion 4a of the annular upwardly projecting portion 4, and thus the inwardly projecting portion 121 of the inwardly projecting portion 121. The protruding end 122 abuts against the outer wall of the upwardly extending portion 6, and the upper surface of the inwardly protruding portion 121 abuts against the outer bottom surface of the arc-shaped extending portion 7 described above, such that the floodlight cover 120 and the heat The sink 1 maintains a circular cross-sectional shape as a whole.

In addition, the translucent cover 120 used in the present invention is formed of transparent or translucent, colorless or colored glass or heat resistant transparent resin which may include an optical dispersion.

The type, composition, and composition ratio of the light diffusing body and the heat-resistant light diffusing light transmitting resin are described in Korean Patent No. 0787049 (registered on Dec. 12, 2007) by the present applicant, an illumination member using the same, and a manufacturing method thereof. Since it is described in detail in the present specification, a detailed description thereof will be omitted.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. This is also within the scope of the present invention.

1: heat pipe type heat sink according to the present invention
2: LED mounting part 2a: LED mounting surface
3: downward protrusion 3a: inclined portion
4: annular upward protrusion 4a: distal end
5: recess 6: upward extension
7: arc-shaped extension part 7a, 7b: locking jaw
8: upward slope
8a: corner 8b: open space
9: airtight space
9a: working fluid (refrigerant) 9b: sintered-metal wick
100: tube type LED lighting lamp according to the present invention
110: LED 111: insulation layer
112: circuit pattern layer 120: floodlight cover
121: inward protrusion 122: protruding end
123: jamming jaw

Claims (12)

An LED mounting unit having a target LED mounting surface;
An upward extension part protruding at both ends of the LED mounting part in a direction opposite to the LED mounting surface along a length extending direction of the LED mounting part, and having a locking step on the outside thereof;
An upwardly inclined portion extending from an inner lower portion of the upwardly extending portions of both sides in an upwardly inclined or curved gradient to form an edge at a central portion thereof;
The sealed space formed by the LED mounting portion and the upward inclined portion is integrally formed:
The refrigerant is filled in the above enclosed space portion under an atmospheric pressure or a reduced pressure atmosphere.
Heat pipe type heat sink for tube type LED lighting lamp. The heat pipe type heat sink according to claim 1, wherein downward projections are integrally formed at both ends of the LED mounting portion along the length extending direction. The heat pipe type heat sink according to claim 2, wherein the inner longitudinal edges of the respective downward protrusions are formed as upward inclined portions. The method of claim 2, wherein the upper extension portions of the both sides are located in the width region of the downward projections of the two sides, the locking jaws of the outer side of each of the upward extensions is formed of the upper and lower locking jaws, A heat pipe type heat sink for a tubular LED lighting lamp, wherein the extension end of the upward extension is integrally formed by an arc-shaped extension to form an open space together with the upward extension and the upward inclination. The heat pipe type heat sink for a tubular LED lighting lamp according to claim 1, wherein said enclosed space portion is formed in a triangular shape or a pentagonal shape by an LED mounting portion, an upwardly inclined portion, and an upwardly extending portion. 3. The heat for tube-shaped LED lighting lamp according to claim 2, wherein an annular upward protrusion extends outwardly opposite to the downward protrusion, and a recess is defined by the annular upward protrusion, the LED mounting portion, and the lower portion of the upward extension. Pipe type heat sink. The heat pipe type heat sink according to claim 4, wherein a plurality of heat dissipation fins are integrally formed above the upward inclined portion in the open space portion. The heat pipe type heat sink according to claim 1, wherein said inner wall of said enclosed space has a sintered-metal wick having a layer thickness of 0.1 to 0.5 mm. The heat pipe type heat sink according to claim 1, wherein said refrigerant is acetone, methanol, ethanol, ammonia water, distilled water, or any mixture thereof. Tubular LED lighting lamps consisting of:
(A) a heat pipe type heat sink for a tubular LED lighting lamp according to claim 1 or 2 or 4 or 6 or 8 or 9;
(B) an insulating layer formed of an anodized film, a ceramic thin film, or a resin thin film laminated on the LED mounting surface of the heat pipe type heat sink for the tube type LED lighting lamp described above;
(C) a conductive circuit pattern layer printed on the above insulating layer;
(D) LED mounted on said conductive circuit pattern layer; And
(E) A projection cover in the form of an annular tube having a cleavage end formed in a longitudinal direction, the inwardly projecting portion having a locking projection fastened to the locking projection of the heat pipe type heat sink for a tubular LED lighting lamp described above. delete The tubular LED lighting lamp according to claim 10, wherein the floodlight cover is formed of transparent or translucent, colorless or colored glass or heat resistant transparent resin which may include an optical dispersion.

Images