DE202008016231U1 - Heat sink module - Google Patents

Abstract

Heat sink module, which contains:
a heat transfer tube (1), the heat transfer tube (1) including a plurality of positioning grooves (11) equiangularly spaced around the circumference thereof;
a radiating fin set (2), said radiating fin set (2) including a plurality of radiating fins (21) respectively fixed to said positioning grooves (11) of said heat transfer tube (1), wherein each of the radiating fins (21) includes a plurality of retaining lugs (212, 213) respectively projecting from an upper and lower side thereof, the retaining lugs (212, 213) of one of the radiating fins (21). each with the retaining lugs (212, 213) of a further of the radiating fins (21) are fixed; and
a heat transfer member (3) attached to a lower side of the heat transfer tube (1) for direct contact with a heat source to transfer heat to the heat transfer tube (1) and the radiation fin set (2 ) to dissipate.

Description

The This utility model relates to heat dissipation technology and more particularly to a heat sink module which includes a heat transfer tube, a A plurality of radiating fins radially around the circumference of the heat transfer tube and are arranged fixed to each other, and a heat transfer element, which at the bottom of the heat transfer tube for a direct contact with a heat source for transmission of heat to the radiating fins for a fast dispersion is included.

Lots Heat sink modules are commercially available. A regular one heat sink contains a heat transfer base element and a plurality of radiating fins which are at the top from the heat transfer base member are arranged. The heat transfer base element and the radiating fins are made of aluminum or copper. The radiation lamellae are by heat bonding by applying from a solder paste or a binder to the heat transfer base member bound. When the heat transfer base element and the radiating fins each made of different metal materials is a nickel coating treatment prior to bonding necessary. This heat sink module manufacturing process is complicated, which leads to high production costs and a low Yield rate leads. Furthermore, a nickel coating causes pollution of the environment.

Further LED projector lamps have a low power consumption characteristic. However, an LED projector lamp has a low working temperature. The power of an LED projector lamp stands dependent on based on their heat dissipation effectiveness. Therefore, it is important to have the heat dissipation efficiency from an LED projector lamp to verbes fibers.

The basic task of the present utility model is in the provision of a heat dissipation module, which solves the above problems.

These The object is solved by the features of claim 1.

The The present invention has been accomplished under the circumstances considered. According to an embodiment of of the present invention contains the Heat sink module a heat transfer tube, a Radiating fin set and a heat transfer element. The radiation lamella set contains a plurality of radiating fins radially peripheral to the heat transfer tube are notched and then fastened together. The heat transfer element is attached to the bottom of the heat transfer tube. While the application becomes the heat transfer element in the close contact with the heat source kept a heat from the heat source to transmit to the radiating fins for rapid dispersion.

According to one Another embodiment of the present invention is the heat dissipation module Practical for use with an LED lamp to heat transfer element in direct contact with the light emitting unit of a sequence of light-emitting diodes of the LED lamp for fast dispersion from heat of to hold the light emitting diodes.

According to one Each further embodiment contains each Radiating fin a plurality of retention approaches at the top and bottom. By means of a fastening of the retaining lugs of a radiating lamella to the retaining lugs of another radiating lamella the radiating fins are fastened together. Furthermore, each one has Radiating louvre their lower retaining lugs at different elevations arranged to become the step-shaped Structure of the heat transfer element for one direct contact, thereby improving the heat transfer efficiency becomes.

According to one Another embodiment of the present invention is an inner End of each radiating fin in a rib end edge to quick attachment to a respective positioning groove on the circumference ribbed by the heat transfer tube, around the contact area between the heat transfer tube and the radiating fins for a quick dissipation of heat to increase.

According to one Another embodiment of the present invention is an inner End of each radiating fin into a rib end edge, which an L-shape, triangular, inverse T- or roller assembly has, for quick attachment in a respective Stellnut ribbed at the periphery of the heat transfer tube to the contact area between the heat transfer tube and to increase the radiation fins for rapid dissipation of heat.

According to another embodiment of the present invention, the heat transfer tube can be extruded directly from a metal material by means of a metal extrusion process, thereby simplifying the manufacture and the manufacturing cost of the heat transfer tube can be reduced.

A embodiment The invention will be described below with reference to the drawings by way of example described. Showing:

1 a top view of an LED lamp to which a heat dissipation module according to the present invention is mounted,

2 an exploded view of the in 1 shown LED lamp,

3 a sectional view of the in 1 shown LED lamp,

4 an enlarged view of a part of the heat transfer tube of the heat dissipation module according to the present invention,

5 a schematic view of a part of the present invention, which indicates a connection between the radiating fins and the heat transfer tube,

6 a plan view of a radiating fin of the radiating fin set of the heat dissipation module according to the present invention,

7 12 is a schematic view showing a rib end edge formed at the inner end of the radiating fin according to the present invention;

8th a schematic view showing the rib end edge of the radiating fin of 7 , which is attached to the heat transfer tube, indicates

9 12 is a schematic view showing another shape of a rib end edge formed at the inner end of the radiating fin according to the present invention;

10 a schematic view showing the rib end edge of the radiating fin of 9 , which is attached to the heat transfer tube, indicates

11 12 is a schematic view showing another shape of a rib end edge formed at the inner end of the radiating fin according to the present invention;

12 a schematic view showing the rib end edge of the radiating fin of 11 , which is attached to the heat transfer tube, indicates

13 12 is a schematic view showing another shape of a rib end edge formed at the inner end of the radiating fin according to the present invention;

14 a schematic view showing the rib end edge of the radiating fin of 13 , which is attached to the heat transfer tube, indicates

15 12 is a schematic view showing another shape of a rib end edge formed at the inner end of the radiating fin according to the present invention;

16 a schematic view showing the rib end edge of the radiating fin of 15 , which is attached to the heat transfer tube, indicates

17 a correspondence of 11 showing the LED lamp in use with an outer shell, prior to charging the outer shell,

18 a correspondence of 17 showing the outer shell attached to the radiating fin set, and

19 a correspondence of 11 however, which indicates an annular outer shell attached to the underside of the radiating fin set.

Referring to 1 to 3 is a spherical heat dissipation module in use with an LED lamp 10 displayed. It should be understood that the spherical heat sink module is applicable to another object or area. For example, the spherical heat sink module may be used to dissipate heat from a heat source (eg, a CPU). As shown, the spherical heat sink module includes a heat transfer tube 1 , a radiation lamella set 2 and a heat transfer element 3 , These components may be made of copper, aluminum, or any of a variety of other heat transfer metallic materials.

The heat transfer tube 1 is how in 2 and 4 shown a hollow tube, which has a plurality of parking grooves 11 and a plurality of V-grooves 12 , which are arranged alternately around the circumference and in the longitudinal direction extend through the upper and lower ends, and a plurality of mounting holes 13 has, which are equiangularly spaced around the inner side wall. The parking grooves 11 are designed to each of the radiating fins 21 from the radiation fin set 2 (S. 5 and 6 ). After insertion of the radiating fins 21 in the parking grooves 11 become the V-grooves 12 deformed, causing the radiation fins 21 firmly attached to the heat transfer tube 1 be attached. The mounting holes 13 at the top of the heat transfer tube 1 used to attach a lamp holder 101 from the LED lamp 10 (S. 2 ).

The radiation lamella set 2 contains a plurality of radiating fins 21 which are arranged together radially to show a substantially hemispherical structure (s. 2 and 5 ). Each radiating lamella 21 has an inner end 211 , which in a respective Stellnut 11 from the heat transfer tube 1 is pressed. By means of a deformation of the V-grooves 12 from the heat transfer tube 1 after insertion from the inner ends 211 from the radiation fins 21 become the radiation fins 21 to the perimeter of the heat transfer tube 1 stapled.

The heat transfer element 3 gets to the bottom of the heat transfer tube 1 attached and in positive engagement with the bottom of the radiating fin set 2 and also kept in close contact with a heat source. The heat source may be, for example, a CPU. According to this embodiment, the light emission unit serves 5 from the LED lamp 10 as a heat source. The light emission unit 5 contains an LED substrate 4 and several strings of LEDs (light emitting diodes). The light emission unit 5 gives off heat when light is emitted. Further, as in 2 and 3 shown has the heat transfer element 3 a stepped flat part, which has several steps 31 and a plurality of fixing through holes 32 and 33 , which are drilled through the top and bottom, has to the mounting holes 13 at the bottom of the heat transfer tube 1 and the LED substrate 4 to fix.

The aforementioned heat transfer tube 1 , the radiation slat set 2 and the heat transfer element 3 are assembled, whereby the desired heat dissipation module is formed. During application, the heat transfer element becomes 3 kept in close contact with the heat source, so that the heat transfer element 3 and the heat transfer tube 1 a heat from the heat source to the radiating fins 21 from the radiation fin set 2 for a quick dispersion to the outside environment. As shown, the heat sink module is in the LED lamp 10 built-in. During operation of the light emission unit 5 from the LED lamp 10 transfer the heat transfer element 3 and the heat transfer tube 1 a heat from the LED substrate 4 from the light emission unit 5 from the LED lamp 10 to the radiating fins 21 from the radiation fin set 2 for quick dispersion to the outside environment. This will change the brightness of the LED lamp 10 elevated.

The heat sink module may also be used to dissipate heat from any of a variety of other heat sources, such as a CPU. In this case, the heat transfer element 3 held in close contact with the surface of the CPU, to transfer heat from the CPU to the radiating fin set 2 for a quick dissipation of heat transfer.

The lamp holder 101 , the LED substrate 4 and the light emission unit 5 from the aforementioned LED lamp 10 are already known. Since the heat sink module of the present invention has excellent heat dissipation efficiency, the light emission unit can 5 from the LED lamp 10 be formed from a high number of LED sequences.

Referring to 6 has every radiating lamella 21 from the radiation fin set 2 retaining lugs 212 and 213 which project from the upper and lower sides, respectively. By means of the holding approaches 212 and 213 become the radiation fins 21 fastened together, as in 2 shown. The holding approaches 212 and 213 each have a holding hole 2121 or 2131 and a hook block 2122 or 2132 which protrudes from the upper or lower side. By means of an intervention from the hook blocks 2122 and 2132 from a radiation lamella 21 into the holding holes 2121 and 2131 from another radiation slat 21 become the radiation fins 21 fastened together.

Furthermore, the lower retaining lugs 213 arranged so as to accommodate the construction of the multiple stages 31 from the heat transfer element 3 correspond. The score 214 on the lower side of each radiating fin 21 is used to facilitate insertion of screws 41 which the LED substrate 4 to the heat transfer element 3 Fasten. With the exception of the attachment function increase the holding approaches 212 and 213 the contact area between the radiating fins 21 and the heat transfer confining element 3 , whereby the heat transfer efficiency is increased. Further, a transfer cover plate 6 at the bottom of the radiating fin set 2 and the heat transfer element 3 be attached.

Referring to 7 and 8th is the inner end of each radiating lamella 21 in a rib end edge 211 for engaging in a respective positioning groove on the circumference of the heat transfer tube 1 ribbed, increasing the bond strength between the radiating fins 21 and the heat transfer tube 1 is improved and the contact area between the radiating fins 21 and the heat transfer tube 1 is increased.

The rib end edge 211 can be created on any of a variety of shapes. In the in 9 and 10 The example shown has the rib end edge 211b an L-shaped profile. In the in 11 and 12 The example shown has the rib end edge 211c a triangular profile on. In the in 13 and 14 The example shown has the rib end edge 211d a roll-shaped profile. In the in 15 and 16 The example shown has the rib end edge 211e an inverse T profile on.

Further, a metal extrusion process may be used to form the heat transfer tube 1 to create which the Stellnuten 11 and V-grooves 12 has arranged around the circumference alternately. The metal extrusion process is suitable for mass production to reduce the cost of manufacturing the heat transfer tube 1 to reduce.

Referring to 17 and 18 is an outer shell 7 on the radiation lamella set 2 attached. The cap-shaped lampshade 7 has a plurality of vents 71 to dissipate heat.

19 shows an alternative form of the outer shell, which with 8th is marked. According to this embodiment, the outer shell 8th a simple ring, which at the periphery of the radiating fin set 2 attached to the lower side.

Further For example, a solid cylindrical heat transfer member may be used be used to replace the heat transfer tube, it means that the heat transfer tube in a hollowed out shape or a massive shape can be created. Furthermore, the heat transfer tube with a round, triangular, rectangular or polygonal cross section be created. Further, the size and shape of the radiating fins and their arrangement is not limited to the above description, the is called, that made various modifications and improvements can be without departing from the scope of the invention. Accordingly, the Invention, except as by the appended claims, not to restrict.

Claims (10)

Heat sink module, which includes: a heat transfer tube ( 1 ), wherein the heat transfer tube ( 1 ) a plurality of parking grooves ( 11 ) equiangularly spaced around the circumference thereof; a radiation lamella set ( 2 ), wherein the radiation lamella set ( 2 ) a plurality of radiating fins ( 21 ), which in each case at the parking grooves ( 11 ) from the heat transfer tube ( 1 ), each of the radiating fins ( 21 ) a plurality of holding approaches ( 212 . 213 ) each projecting from an upper and lower side thereof, wherein the retaining lugs ( 212 . 213 ) of one of the radiating fins ( 21 ) each with the holding approaches ( 212 . 213 ) from another of the radiation fins ( 21 ) are attached; and a heat transfer element ( 3 ), which at a lower side of the heat transfer tube ( 1 ) is mounted for direct contact with a heat source to transfer heat to the heat transfer tube ( 1 ) and the radiation lamella set ( 2 ) to dissipate. Heat dissipation module according to claim 1, wherein the heat transfer tube ( 1 ), the heat transfer element ( 3 ) and the radiation fins ( 21 ) of the radiating fin set ( 2 ) are made of a heat transfer metal material selected from a material group containing copper and aluminum. Heat dissipation module according to claim 1, wherein the heat transfer tube ( 1 ) a plurality of V-grooves ( 12 ), which in each case at the periphery thereof between in each case two adjoining positioning grooves ( 11 ) for the deformation processing of the positioning grooves ( 11 ) after insertion of the radiation fins ( 21 ) are formed. Heat dissipation module according to claim 1, wherein the heat transfer tube ( 1 ) a plurality of mounting holes ( 13 ) formed on upper and lower sides of an inner wall thereof. Heat dissipation module according to claim 1, wherein the heat transfer tube ( 1 ) has an upper side, which on a lamp holder ( 101 ), wherein the heat transfer element ( 3 ) holds a heat source comprising a light emitting device ( 5 ) which is an LED substrate ( 4 ) and several episodes of light emitting diodes. A heat dissipation module according to claim 1, wherein each of the retention lugs ( 212 . 213 ) of each of the radiating fins ( 21 ) a holding hole ( 2121 . 2131 ) and a hook block ( 2122 . 2132 ) contains. A heat sink module according to claim 1, wherein the heat transfer element ( 3 ) is a step-shaped flat element, each radiation lamella ( 21 ) of the radiating fin set ( 2 ) a plurality of the holding approaches ( 212 . 213 ), which are arranged on the lower side thereof at different elevations, to the stepped structure of the heat transfer element ( 3 ) correspond to. A heat dissipation module according to claim 1, wherein each of the radiating fins ( 21 ) a rib inner end edge ( 211 ; 211b ; 211c ; 211d ; 211e ), which in each case at the Stellnuten ( 11 ) from the heat transfer tube ( 1 ) is attached. Heat dissipation module according to claim 1, wherein the heat transfer tube ( 1 ) is extruded from a metal material. A heat dissipation module according to claim 1, wherein the radiating fin set ( 2 ) has a circumference at which an outer shell ( 8th ) is attached.