TWM480099U - A combined radiator - Google Patents

Abstract

The present creation discloses a combined radiator. The combined radiator comprises a heat radiation base and a reinforcing structure. The heat radiation base comprises a first heat radiation base and a second heat radiation base. The first heat radiation base has a first side. The first side has a convex structure. The second heat radiation base has a third side which is opposite to the first side. The third side has a concave groove for receiving the convex structure to make the first heat radiation base engaged with the second heat radiation base. The reinforcing structure is an L-shaped reinforcing structure having a locking piece and an engaging piece. The reinforcing structure is installed in the heat radiation base to enhance the connection between the first heat radiation base and the second heat radiation base. The combined radiator of the present creation has extension and enhances the connected functionality to be combined into any area of the radiator.

Description

A combinable radiator

The present invention discloses a combinable heat sink, and in particular to a configurable heat sink base having a reinforced structure capable of carrying a set of heat sink fins.

In a computer or electronic equipment, the central processing unit (CPU) is also responsible for the operation of a large number of electronic signals. In order to effectively process astronomical data, the speed of the central processing unit can be said to be very amazing, so when the central When the processor is running at high speed, it is difficult to avoid high temperature, and as the running time is lengthened, the temperature will rise rapidly, which will eventually reduce the efficiency of the central processing unit and even cause the central processing unit to stop operating and fail to recover.

Therefore, in order to keep the central processing unit at a certain operating temperature, a set of heat sinks is disposed on the surface of the central processing unit. The most common example is a blade type heat sink made of aluminum extrusion, which is quickly absorbed through the heat sink. The combination of thermal energy and conduction into the cooling airflow does solve the high temperature problem of the central processor. However, once the heat sink formed in a fixed shape by the aluminum extrusion type is molded, the overall shape and mechanism formed by the heat dissipating blade and the aluminum extruded base are fixed, and cannot be arbitrarily changed. In addition, in the manufacturing process, the long strip of aluminum material needs to be cut and cut in its required specifications, and needs to be polished, so that the processing procedure is complicated and waste is generated during cutting.

Moreover, in actual use, when the heat sink is deformed or damaged, the integrally formed heat sink is It is not possible to replace the damaged part locally, for example, if the heat sink is damaged due to careless installation, falling collision, or fixing the heat sink with screws or tools, in order to avoid affecting the heat dissipation effect, only the whole part is removed. Replacing a new radiator will not only waste time, but also cause confusion.

In view of this, the present invention proposes a combined heat sink that provides a configurable heat sink base having a reinforced structure, wherein the heat sink base can also carry a conventional heat sink or be integrally formed with a conventional heat sink, and then In addition, the heat sink base is combined one by one according to the installation specification requirements, thereby improving the lack of the aforementioned prior art.

The inventive combined heat sink includes a heat sink base and a reinforcing structure. The heat dissipation base includes a first base and a second base, the first base has a first side, the first side has a first convex structure, and the second base has a third side opposite to the first side The third side has a first concave groove for receiving the first convex structure to engage the first base with the second base. The reinforced structure is mounted on the heat dissipation base to strengthen the connection between the first base and the second base.

The reinforcing structure is an L-shaped reinforcing structure, and has a locking piece and a clamping piece. The locking piece has two locking holes, and the engaging piece has a two-ladder structure. The first base has a first bottom surface, and the second base has a second bottom surface. The first bottom surface and the second bottom surface respectively have a ladder-shaped fixing hole for receiving the two ladder-shaped structures of the engaging piece.

The first base further has a second side, and the second base further has a fourth side, and each of the second side and the fourth side has a screw hole. The L-shaped reinforced structure is respectively fixed to the second side and the fourth side by two screws respectively passing through the two locking holes of the locking piece. Two screw holes.

Furthermore, the combined heat sink of the present invention may further comprise a set of heat dissipation fins mounted on the heat dissipation base. The heat dissipation fins of the group and the heat dissipation base are different heat conduction materials. The heat dissipation fins and the heat dissipation base are the same heat conduction material.

Compared with the prior art, the present invention has the characteristics of infinitely amplifying the connection and the function of the enhanced connection. The present invention can be combined into a heat sink of any area, and the heat dissipation surface surface can exert a better heat dissipation effect. At the same time, this creation can be applied to a wide variety of products that require heat dissipation, no need to mold the corresponding molds, update the damaged parts of the heat sink, and improve the conventional technology due to different specifications of the heat sink. Inventory pressure and procurement costs, which in turn significantly reduce costs. In addition, the simple structure of the creation can facilitate installation and operation, and is of considerable benefit to a small variety of products.

Because the creation structure is novel and can provide industrial use, and it has improved efficiency, it applies for a new patent according to law. The above and other objects, features and advantages of the present invention will become more apparent and understood.

1‧‧‧Combinable radiator

10‧‧‧heating base

12‧‧‧First base

122‧‧‧First side

1222‧‧‧First convex structure

124‧‧‧ first bottom surface

126‧‧‧ second side

128‧‧‧ fifth side

1282‧‧‧Second screw hole

14‧‧‧Second base

142‧‧‧ third side

1422‧‧‧First concave groove

144‧‧‧second bottom surface

1242, 1442‧‧‧ ladder type fixing holes

146‧‧‧ fourth side

1262, 1462‧‧‧ screw holes

16‧‧‧ front end

18‧‧‧ third base

20‧‧‧Strengthen structure

22‧‧‧Locks

222‧‧‧Lock hole

24‧‧‧Clocks

242‧‧‧ ladder structure

26‧‧‧ screws

30‧‧‧Fixing fin set

FIG. 1 is a schematic view showing an embodiment of the inventive combined heat sink.

Figure 2 is a perspective exploded view of the heat sink base of the present invention.

Figure 3 is a three-dimensional diagram showing the enhanced structure of the creation.

Figure 4 is a perspective view showing the bottom surface of the heat sink base of the present invention.

FIG. 5 is a schematic view showing another embodiment of the present invention.

In order to make the purpose, features and advantages of the present invention more obvious and easy to understand, the detailed implementation of the present invention will be described in detail below with reference to the accompanying drawings.

First, please refer to FIG. 1 , which is a schematic diagram showing an embodiment of the presently combinable heat sink. The present invention proposes a combinable heat sink 1 comprising a heat sink base 10 and a reinforcing structure 20. The heat dissipation base 10 includes a first base 12 and a second base 14. In this embodiment, the first base 12 is coupled to the second base 14 to form a heat dissipation base 10, but not limited thereto. In practical application, the creation also allows the composite array base to be engaged with each other, and combined into a heat sink base 10 of any area, which has a better heat dissipation effect by a large heat dissipation surface area, and can also be applied to heat dissipation of different size specifications. In addition, in practical applications, the heat sink base 10 can be made of a material having good thermal conductivity such as aluminum, aluminum alloy, copper or copper alloy. The reinforcing structure 20 is mounted on the front end portion 16 of the heat dissipation base 10 for reinforcing the connection between the first base 12 and the second base 14. The heat dissipating fin set 30 is further disposed on the heat dissipating base 10, but not limited thereto. In practical applications, the heat dissipating base and the heat dissipating fin set are also integrally formed. Moreover, in the present embodiment, the heat dissipation fin group 30 is assembled by a plurality of combinable heat dissipation fins by mutual engagement, but not limited thereto. In practical applications, the heat dissipation fin group 30 can also be referred to as a one-piece heat sink fin set, which belongs to its category. In addition, in practical applications, the heat sink fin set 30 can be made of a material having good thermal conductivity such as aluminum, aluminum alloy, copper or copper alloy. .

Furthermore, please refer to FIG. 1 and FIG. 2 , wherein FIG. 2 is a three-dimensional exploded view of the heat dissipation base of the present invention. The combinable heat sink 1 includes a heat sink base 10 and a reinforcing structure 20 . The heat dissipation base 10 includes a first base 12 and a second base 14. The first base 12 has a first The first side 122 has a first convex structure 1222, the second base 14 has a third side 142 opposite to the first side 122, and the third side 142 has a first concave groove. The slot 1422 is configured to receive the first convex structure 1222, so that the first base 12 is engaged with the second base 14. In practical applications, the first side 122 of the first base 12 and the third side of the second base 14 The shape of the side 142 can also be formed by various polygons and can have the effect of achieving mutual engagement.

Next, please refer to FIG. 2, FIG. 3 and FIG. 4, wherein FIG. 3 is a three-dimensional diagram showing the structure of the creation reinforcement, and FIG. 4 is a three-dimensional diagram showing the bottom surface of the creation heat dissipation base. The inventive combined heat sink 1 includes a heat sink base 10 and a reinforcing structure 20 . First, the reinforcing structure 20 is an L-shaped reinforcing structure 20 having a locking piece 22 and a locking piece 24, the locking piece 22 has two locking holes 222, and the engaging piece 24 has a two-ladder structure 242. The locking piece 22 and the engaging piece 24 are integrally formed to form an L-shaped reinforcing structure 20. Furthermore, the L-shaped reinforcing structure 20 is mounted on the front end portion 16 of the heat dissipation base 10 for reinforcing the connection between the first base 12 and the second base 14. In this embodiment, the engaging piece 24 has a two-ladder structure 242, but not limited thereto. In practical applications, the ladder structure 242 can also be configured by various polygons. At the same time, the first base 12 has a first bottom surface 124, and the second base 14 has a second bottom surface 144. In this embodiment, the first bottom surface 124 and the second bottom surface 144 each have a ladder-shaped fixing hole 1242. 1442, but not limited thereto. In practical applications, the ladder-shaped fixing holes 1242 and 1442 can also be used for accommodating the two ladder-shaped structures 242 of the engaging piece 24 for the holes formed by the various polygons. Furthermore, the first base 12 further has a second side 126, and the second base 14 further has a fourth side 146. At the same time, the second side 126 and the fourth side 146 respectively have a screw hole 1262, 1462, and the L-shaped reinforcing structure 20 passes through the two locking holes 222 of the locking piece 22 respectively by the two screws 26, thereby locking Two screw holes fixed to the second side 126 and the fourth side 146 1262, 1462. Therefore, the ladder-shaped fixing holes 1242 and 1442 respectively provided by the first bottom surface 124 and the second bottom surface 144 are used for accommodating the two ladder-shaped structures 242 of the engaging piece 24 of the reinforcing structure 20, and the L-shaped reinforcing structure 20 is added. The locking piece 22 is locked to the second side edge 126 and the second side edge 146 of the two screw holes 1262, 1462. The L-shaped reinforcing structure 20 is mounted on the front end portion 16 of the heat dissipation base 10, and can be used for The connection between the first base 12 and the second base 14 is strengthened.

Finally, please refer to Figure 2, Figure 3, Figure 4 and Figure 5. FIG. 5 is a schematic view showing another embodiment of the present invention. The present embodiment is applied to the complex array bases for mutual engagement. First, the heat sink base 10 includes a third base 18 in addition to the first base 12 and the second base 14. However, in practice, the number of the bases can be determined by the size of the product that needs to be dissipated. . Moreover, in the case that the first base 12 and the second base 14 have been engaged, the first base 12 further has a fifth side 128 corresponding to the first side 122. In this embodiment, the fifth side The side 128 is a concave groove (not shown) for connecting the third base 18, while the sixth side of the third base 18 (not shown) corresponds to the concave groove of the fifth side 128. (not shown in the figure) has a convex structure (not shown in the figure), which can be engaged with the fifth side 128 of the first base 12, but not limited thereto. In practical applications, The fifth side 128 of the first base 12 can be a convex structure or a concave groove (not shown) for connecting the third base 18 while the sixth side of the third base 18 (not shown) In the figure, the fifth side 128 has a concave groove or a convex structure which can be engaged with the fifth side 128 of the first base 12. Next, the first base 12 has a first bottom surface 124. The first bottom surface 124 has a ladder-shaped fixing hole 1242 and a second ladder-shaped fixing hole (not shown), and the third base 18 also has a The third bottom surface (not shown) has a ladder-shaped fixing hole (not shown in the drawing). The second ladder type fixing hole is provided by the first bottom surface 124 (not shown in the figure) The middle type and the third bottom surface have ladder-shaped fixing holes (not shown) for receiving the two ladder-shaped structures 242 of the engaging pieces 24 of the reinforcing structure 20. Furthermore, the fifth side 128 has a second screw hole 1282 and the sixth side has a screw hole (not shown), and the L-shaped reinforcing structure 20 passes through the locking piece 22 by the two screws 26 respectively. The second locking hole 222 is locked to the second screw hole 1282 of the fifth side 128 and the screw hole of the sixth side (not shown). Therefore, by attaching the L-shaped reinforcing structure 20 to the front end portion 16 of the heat dissipation base 10, the connection between the first base 12, the second base 14, and the third base 18 can be enhanced.

Compared with the prior art, the present invention proposes a combinable heat sink comprising a heat sink base and a reinforcing structure. The heat dissipation base includes a first base and a second base, and the first concave groove of the third side of the second base is used for receiving the first convex structure of the first side of the first base, so that the heat dissipation base The first base is engaged with the second base. At the same time, the reinforced structure is installed on the heat dissipation base to strengthen the connection between the first base and the second base. Therefore, the creation has the characteristics of infinitely amplifying the connection and the function of the reinforced connection, and can be combined into a heat sink of any area, and the heat dissipation effect is achieved by the large heat dissipation surface area, and the creation can be applied to each A variety of products that require heat dissipation, no need to mold the mold to prepare the corresponding mold, update the damaged part of the heat sink, and improve the inventory pressure and purchase cost of the conventional technology due to different specifications of the heat sink. Significantly reduce costs. In addition, it is easy to install and operate with a simple structure, which is quite helpful for a small number of products.

The features and spirit of the present invention are more clearly described in the above detailed description of the preferred embodiments, and the scope of the present invention is not limited by the preferred embodiments disclosed herein. On the contrary, it is intended to cover all kinds of changes and equivalences within the scope of the patent application to which the present invention is intended. Therefore, the scope of the patent scope applied for by this creation should be The broadest interpretation is based on the above description so that it covers all possible changes and arrangements of equality.

1‧‧‧Combinable radiator

10‧‧‧heating base

12‧‧‧First base

14‧‧‧Second base

16‧‧‧ front end

20‧‧‧Strengthen structure

22‧‧‧Locks

24‧‧‧Clocks

26‧‧‧ screws

30‧‧‧Fixing fin set

Claims (7)

A heat dissipating heat sink comprising: a heat dissipating base, comprising a first base and a second base, the first base having a first side, the first side having a first convex structure, The second base has a third side opposite to the first side, the third side has a first concave groove for receiving the first convex structure, so that the first base is engaged with The second base; and a reinforcing structure are disposed on the heat dissipation base for reinforcing the connection between the first base and the second base. The detachable heat sink according to claim 1, wherein the reinforced structure is an L-shaped reinforced structure, and has a locking piece and a locking piece, wherein the locking piece has two locking holes, and the locking piece has two locking holes, The engaging piece has a two-ladder structure. The detachable heat sink of claim 2, wherein the first base further has a first bottom surface, and the second base further has a second bottom surface, the first bottom surface and the second bottom surface respectively The utility model has a ladder type fixing hole for receiving the two ladder type structure of the engaging piece. The detachable heat sink of claim 2, wherein the first base further has a second side, the second base further has a fourth side, the second side and the fourth Each side has a screw hole. The reconfigurable heat sink of claim 4, wherein the L-shaped reinforcing structure is respectively traversed by the two locking holes of the locking piece by two screws, thereby being locked to the second side and Two screw holes on the fourth side. The reconfigurable heat sink of claim 2, wherein the locking piece and the engaging piece are integrally formed to form the L-shaped reinforcing structure. The reconfigurable heat sink according to claim 1, wherein the combinable type The heat sink further includes a heat dissipation fin set mounted on the heat dissipation base.