CN215935351U - Copper pipe for heat dissipation micro fan - Google Patents

Abstract

The utility model is suitable for the field of copper pipe heat dissipation, and provides a copper pipe for a heat dissipation micro fan. The sleeve is internally provided with a heat conduction copper pipe and forward threads, the outer surface of the heat conduction copper pipe is provided with drainage lines, the inner side of the heat conduction copper pipe is provided with a power supply contact rod containing a wire, the right end of the heat conduction copper pipe is a heat absorption end, the heat absorption end is provided with a heat absorption sheet, a good heat absorption material is attached to the outer side of the heat absorption sheet, the other end of the heat conduction copper pipe is a heat dissipation end, the heat dissipation end is provided with a reinforced heat dissipation sheet, the reinforced heat dissipation sheet is provided with a heat dissipation gully and a power supply contact point, the lower side of the reinforced heat dissipation sheet is provided with a rotary bearing, the rotary bearing is provided with an electric wind wheel, the rotary bearing is externally connected with a sleeve cover, the sleeve cover is internally provided with reverse threads, and the sleeve cover is externally provided with a control console. The upper side of the console is provided with a heat absorption sheet temperature display screen. The heat dissipation gullies and the drainage lines are respectively arranged on the surfaces of the reinforced heat dissipation fins and the heat conduction copper pipe. Through the arrangement of the utility model, the heat dissipation work of the miniature fan is conveniently and effectively realized.

Description

Copper pipe for heat dissipation micro fan

Technical Field

The utility model belongs to the field of copper pipe heat dissipation, and particularly relates to a copper pipe for a heat dissipation micro fan.

Background

At the present stage, people have a new and different life, the economic society develops rapidly, and the rhythm of life is accelerated, so that a convenient and quick product is more favored by people, electronic products are used as main articles in a plurality of devices, and the heat dissipation problem of the product is already put in front of people along with the continuation of the use time, so that the people should know the heat dissipation problem in advance. For example, in the hot season of weather, the fan, the air conditioner is indispensable, people go out outside, so miniature fan will be indispensable, and miniature fan has that the structure size is little, the characteristics that power consumption is low, and the reynolds number that inside air flows is low, therefore miniature fan's device structure requires highly to when its long-time operation, the original piece that generates heat can produce a large amount of heat energy, and the heat energy gathers too much and must influence its operating condition and product property ability. Then the heat dissipation performance and the service performance of the heat dissipation device are designed and used uniformly. However, in order to achieve the purpose of heat dissipation of the micro fan, natural cooling and contact heat dissipation are mostly achieved in the market. When the micro fan is used for a long time, the heat dissipation device is not easy to radiate a large amount of heat energy, so that the heat dissipation device for the micro fan in a long-time working state is needed to achieve a good heat dissipation purpose under the condition that the work of the micro fan is not influenced.

However, in the implementation, the heat dissipation effect and the heat dissipation effect of the micro fan are related to the operation state of the micro fan and the heat absorption performance of the heat absorption material, so the specific use effect is still to be counted.

SUMMERY OF THE UTILITY MODEL

The utility model provides a copper pipe for a heat dissipation micro fan, and aims to solve the problem that the heat dissipation performance of the micro fan is poor due to the lack of a copper pipe device of the heat dissipation micro fan in the market.

The utility model is realized in such a way that the copper tube for the heat radiation micro fan comprises a heat conduction copper tube, a sleeve and a reinforced heat radiation fin, the method is characterized in that: the sleeve is internally provided with a heat conduction copper pipe and forward threads, the outer surface of the heat conduction copper pipe is provided with drainage lines, the inner side of the heat conduction copper pipe is provided with a power supply contact rod containing a wire, the left side of the power supply contact rod containing the wire is provided with a power supply contact point I and a wire hole, the right end of the heat conduction copper pipe is a heat absorption end, the heat absorption end is provided with a heat absorption sheet, the outer side of the heat absorption sheet is attached with a heat absorption material, the other end of the heat conduction copper pipe is a heat dissipation end, the heat dissipation end is provided with a strengthened heat dissipation sheet, the strengthened heat dissipation sheet is provided with a heat dissipation gully and a power supply contact point II, the lower side of the strengthened heat dissipation sheet is provided with a rotating bearing, the rotating bearing is provided with an electric wind wheel, the rotating bearing is externally connected with a sleeve cover, reverse threads are arranged in the sleeve cover, and a control console is arranged outside the sleeve cover. An electric wind wheel control switch and a charging socket are arranged on the console. The upper side of the console is provided with a heat absorption sheet temperature display screen. The heat dissipation gullies and the drainage lines are respectively attached to the surfaces of the enhanced heat dissipation fins and the heat conduction copper pipe.

Furthermore, the heat absorbing material is adhered to the outer side of the heat absorbing sheet and is in close contact with the heat dissipating element.

Furthermore, a small distance is reserved between the electric wind wheel and the strengthening radiating fins.

Furthermore, a certain gap is formed between the heat conducting copper pipe and the sleeve.

Furthermore, a plurality of radiating grooves are uniformly distributed on the reinforced radiating fins.

Further, the electric wind wheel is larger than the strengthening radiating fins.

Furthermore, the strengthening radiating fins are positioned in the vortex generated by the operation of the electric wind wheel.

The beneficial technical effects related to the implementation of the utility model are as follows: firstly, because the utility model is provided with the heat absorbing sheet, and the heat absorbing material is attached to the outer side of the heat absorbing sheet and is in close contact with the heat dissipation element, the heat energy generated by the heat dissipation element can be fully absorbed. Because the electric wind wheel is arranged and a small distance is reserved between the electric wind wheel and the reinforced radiating fins, the wind flow generated by the work of the electric wind wheel can be blown to the reinforced radiating fins in a full amount, and the heat radiating effect of the reinforced radiating fins is better. Because the heat-radiating copper pipe is arranged and a certain gap is formed between the heat-conducting copper pipe and the sleeve, the heat-conducting copper pipe can be surrounded by wind generated by the work of the electric wind wheel in the gap. Because the utility model is provided with the heat dissipation gullies which are uniformly distributed and are provided with a plurality of heat dissipation gullies, the heat dissipation speed of the reinforced heat dissipation fin is faster. Because the electric wind wheel is arranged and is slightly larger than the reinforced radiating fins, the wind current can be ensured to enter the gap through the reinforced radiating fins and the drainage lines. Because the reinforced radiating fins are arranged and positioned in the vortex generated by the work of the electric wind wheel, the utility model can ensure that the reinforced radiating fins can fully radiate heat, thereby improving the radiating performance.

Drawings

FIG. 1 is a schematic view of a first perspective structure of the present invention;

FIG. 2 is a partial structural view of a second viewing angle region A according to the present invention;

FIG. 3 is an enlarged view of a portion of the structure of area A of the present invention;

FIG. 4 is a schematic view of a third viewing angle B region according to the present invention;

FIG. 5 is an enlarged view of the partial structure of the region B of the present invention;

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the utility model and are not intended to limit the utility model.

It should be noted that the heat conducting copper tube 2, the heat absorbing material 15, the reinforced heat sink 14, the electric wind wheel 18, the rotary bearing 17, the heat absorbing sheet 4, and the power contact bar 5 including the wire are all in the prior art, and are common knowledge of those skilled in the art, and are not described herein again.

Referring to fig. 1 to 5, the present invention relates to a copper pipe for a heat dissipation micro fan, which comprises a heat conduction copper pipe 2, a sleeve 3 and a reinforced heat dissipation fin 14, and is characterized in that the heat conduction copper pipe 2 and a forward thread 19 are arranged in the sleeve 3, a drainage line 6 is arranged on the outer surface of the heat conduction copper pipe 2, a power contact rod 5 containing a wire is arranged on the inner side, a first power contact 12 and a wire hole 11 are arranged on the left side of the power contact rod 5 containing the wire, the right end of the heat conduction copper pipe 2 is a heat absorption end, a heat absorption sheet 4 is arranged on the heat absorption end, a heat absorption material 15 is attached to the outer side of the heat absorption sheet 4, the other end of the heat conduction copper pipe 2 is a heat dissipation end, the reinforced heat dissipation fin 14 is arranged on the heat dissipation end, a heat dissipation groove 13 and a second power contact 16 are arranged on the reinforced heat dissipation fin 14, a rotary bearing 17 is arranged on the lower side of the reinforced heat dissipation fin 14, an electric wind wheel 18 is arranged on the rotary bearing 17, the rotary bearing 17 is externally connected with a sleeve cover 1, reverse threads 20 are arranged in the sleeve cover 1, and a control console 8 is arranged outside the sleeve cover 1. An electric wind wheel control switch 9 and a charging socket 7 are arranged on the control console 8. The upper side of the control console 8 is provided with a heat absorption sheet temperature display screen 10. The heat dissipation grooves 13 and the drainage lines 6 are respectively disposed on the surface of the enhanced heat dissipation fins 14 and the surface of the heat conduction copper pipe 2.

The heat absorbing material 15 attached to the outer side of the heat absorbing sheet 4 is in close contact with the heat dissipating element, so that the heat energy dissipated by the heat dissipating element can be fully absorbed by the heat absorbing sheet 4, and the heat absorbing capacity of the heat absorbing sheet 4 is improved.

A small distance is reserved between the electric wind wheel 18 and the reinforced radiating fins 14, so that wind generated by the work of the electric wind wheel 18 can completely cover the reinforced radiating fins 14, and the radiating speed of the reinforced radiating fins is increased.

A certain gap is arranged between the heat conduction copper pipe 2 and the sleeve 3, so that wind generated by the work of the electric wind wheel can surround the heat conduction copper pipe in the gap

The enhanced heat sink 14 has a plurality of heat dissipation grooves 13 uniformly distributed thereon, so that the enhanced heat sink can dissipate heat synchronously to improve its heat dissipation capability.

The electric wind wheel 18 is larger than the reinforced radiating fins 14, so that wind flow can smoothly enter the drainage lines 6 through the reinforced radiating fins 14.

The reinforced radiating fins 14 are positioned in the vortex generated by the operation of the electric wind wheel 18, so that the reinforced radiating fins 14 can be ensured to start cooling and radiating at the first time.

The working principle of the utility model is as follows: firstly, the electric quantity is ensured to be sufficient, the sleeve cover 1 is matched with the sleeve 3 through the reverse threads 20 on the sleeve cover and the forward threads 19 on the sleeve 3, the first power supply contact point 12 is in contact with the second power supply contact point 16, the electric wind wheel 18 is in a standby working state, the heat absorption material 15 is in sufficient contact with a heat dissipation element and starts to absorb heat, the heat conduction copper pipe 2 is used for transferring the heat to the reinforced heat dissipation fins 14, the electric wind wheel 18 is opened through the electric wind wheel switch 9 on the console 8, and at the moment, the wind flow can blow to the reinforced heat dissipation fins 14 to accelerate the heat dissipation speed of the reinforced heat dissipation fins 14. When the temperature of the heat absorption sheet temperature display screen 10 is normal, the electric wind wheel 18 can be closed to complete the heat dissipation work of the micro fan.

The beneficial technical effects related to the implementation of the utility model are as follows: firstly, because the utility model is provided with the heat absorbing sheet 4, and the heat absorbing material 15 is attached to the outer side 4 of the heat absorbing sheet and is in close contact with the heat dissipation element, the heat energy generated by the heat dissipation element can be fully absorbed. Because the electric wind wheel 18 is arranged and a small distance is reserved between the electric wind wheel 18 and the reinforced radiating fins 14, the wind flow generated by the work of the electric wind wheel 18 can be blown to the reinforced radiating fins 14 in a full amount, and the heat radiating effect of the reinforced radiating fins 14 is better. Because the heat conduction copper pipe 2 is arranged and a certain gap is formed between the heat conduction copper pipe 2 and the sleeve 3, the wind generated by the work of the electric wind wheel 18 can surround the heat conduction copper pipe 2 in the gap. Because the present invention is provided with a plurality of heat dissipation grooves 13, and the heat dissipation grooves 13 are uniformly distributed, the heat dissipation speed of the enhanced heat sink 14 is faster. Because the electric wind wheel 18 is arranged, and the electric wind wheel 18 is slightly larger than the reinforced radiating fins 14, the wind current can be ensured to enter the gaps through the reinforced radiating fins 14 and the drainage lines 6. Because the reinforced radiating fins 14 are arranged and positioned in the vortex generated by the operation of the electric wind wheel 18, the reinforced radiating fins 14 can be ensured to fully radiate heat, so that the radiating performance is improved.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the utility model, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (7)

1. A copper pipe for a heat dissipation micro fan comprises a heat conduction copper pipe (2), a sleeve (3) and a reinforced heat dissipation fin (14), and is characterized in that the heat conduction copper pipe (2) and a forward thread (19) are arranged in the sleeve (3), a drainage line (6) is arranged on the outer surface of the heat conduction copper pipe (2), a power supply contact rod (5) containing a lead is arranged on the inner side of the heat conduction copper pipe (2), a power supply contact point I (12) and a lead hole (11) are arranged on the left side of the power supply contact rod (5) containing the lead, the right end of the heat conduction copper pipe (2) is a heat absorption end, a heat absorption piece (4) is arranged on the heat absorption end, a heat absorption material (15) is attached to the outer side of the heat absorption piece (4), the other end of the heat conduction copper pipe (2) is a heat dissipation end, the heat dissipation end is provided with the reinforced heat dissipation fin (14), and a heat dissipation groove (13) and a power supply contact point II (16) are arranged on the reinforced heat dissipation fin (14), the heat dissipation device is characterized in that a rotary bearing (17) is arranged on the lower side of the reinforced heat dissipation fin (14), an electric wind wheel (18) is arranged on the rotary bearing (17), the rotary bearing (17) is connected with a sleeve cover (1) externally, reverse threads (20) are arranged in the sleeve cover (1), a control console (8) is arranged outside the sleeve cover (1), an electric wind wheel control switch (9) and a charging socket (7) are arranged on the control console (8), a heat absorption sheet temperature display screen (10) is arranged on the upper side of the control console (8), and the heat dissipation gully (13) and the drainage line (6) are respectively attached to the surfaces of the reinforced heat dissipation fin (14) and the heat conduction copper pipe (2).

2. The copper tube for a heat dissipating micro-fan as claimed in claim 1, wherein: the outer side of the heat absorbing sheet (4) is attached with a heat absorbing material (15) which is in close contact with a heat dissipating element.

3. The copper tube for a heat dissipating micro-fan as claimed in claim 1, wherein: a small distance is reserved between the electric wind wheel (18) and the strengthening radiating fins (14).

4. The copper tube for a heat dissipating micro-fan as claimed in claim 1, wherein: a certain gap is formed between the heat conduction copper pipe (2) and the sleeve (3).

5. The copper tube for a heat dissipating micro-fan as claimed in claim 1, wherein: the reinforcing radiating fins (14) are provided with a plurality of radiating grooves (13) which are uniformly distributed.

6. The copper tube for a heat dissipating micro-fan as claimed in claim 1, wherein: the electric wind wheel (18) is larger than the reinforced radiating fins (14).

7. The copper tube for a heat dissipating micro-fan as claimed in claim 1, wherein: the reinforced radiating fins (14) are positioned in the vortex generated by the operation of the electric wind wheel (18).

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