CN215177207U - 5G is cut straightly formula aluminum alloy fin for basic station convenient to installation - Google Patents

Abstract

The utility model discloses a 5G basic station is with cuting straightly formula aluminum alloy fin convenient to installation, including heat-conducting plate, fixed plate and heat radiation fins, the slot has all been seted up on the top of heat-conducting plate, one side on fixed plate top sets up arrangement structure, arrangement structure includes the connecting rod, draws handle, expanding spring, clamp plate and fixed block, the inside on the fixed plate top is inserted to the connecting rod, the top of connecting rod is fixed with draws the handle. The utility model discloses an it draws the drive clamp plate upward movement to drag, and the expanding spring atress shrink simultaneously, then move the heat-conducting plate and put to the bottom of clamp plate, draw the handle through loosening, make expanding spring promote the clamp plate downstream, promote the surface that the heat-conducting plate hugs closely the basic station shell and dispel the heat, go into the inside of clamp plate through the fixed block card, prevent that the heat-conducting plate from to one side landing, realized the quick installation function of this device from this, the quick installation of the device of being convenient for improves work efficiency.

Description

5G is cut straightly formula aluminum alloy fin for basic station convenient to installation

Technical Field

The utility model relates to a fin technical field, in particular to 5G basic station is with cuting straightly formula aluminum alloy fin convenient to installation.

Background

With the development of information communication, 5G networks are erected in succession, the efficiency of information transmission is accelerated, and the delay of information is reduced, while 5G base stations are required to be set for laying the 5G networks so as to transfer and transmit information, and the device is set to dissipate heat of the 5G base stations so as to reduce the temperature in the base stations and prevent the electronic elements in the base stations from being damaged by overhigh temperature;

traditional 5G basic station is with cuting straightly formula aluminum alloy fin is using, and the installation needs use various instruments to carry out fixed mounting, and the process is loaded down with trivial details and consumes manpower and materials, leads to the practicality of device lower.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

The utility model aims at providing a 5G is cut straightly formula aluminum alloy fin for base station convenient to installation for solve the current 5G base station of being convenient for installation and cut straightly the defect that formula aluminum alloy fin is not convenient for install with cutting straightly.

(II) contents of utility model

In order to solve the technical problem, the utility model provides a following technical scheme: the utility model provides a G basic station is with cuting straightly formula aluminum alloy fin convenient to installation, includes heat-conducting plate, fixed plate and heat radiation fins, the slot has all been seted up on the top of heat-conducting plate, and the inside of slot is provided with heat radiation fins, the silicone grease has been paintd to the bottom of heat-conducting plate, the both sides of heat-conducting plate are provided with the fixed plate, the bottom mounting of fixed plate has the basic station shell, one side on fixed plate top sets up arrangement structure, arrangement structure includes the connecting rod, draws handle, expanding spring, clamp plate and fixed block, the connecting rod is inserted and is established the inside on fixed plate top, the top of connecting rod is fixed with and is drawn the handle.

Preferably, the bottom end of the connecting rod is fixed with a pressing plate, the outer side of the connecting rod is sleeved with a telescopic spring, and a fixing block is arranged inside the bottom end of the pressing plate.

Preferably, the connecting rod extends to the top of fixed plate and is connected with the pull handle, constitute welding integrated structure between fixed block and the heat-conducting plate.

Preferably, a heat conduction structure is arranged inside the bottom end of the heat conduction plate and comprises a heat absorption plate, cooling liquid, a capillary copper pipe and a graphite sheet, the graphite sheet is fixed inside the bottom end of the heat conduction plate, the capillary copper pipe is inserted into the graphite sheet, the cooling liquid is arranged inside the capillary copper pipe, and the heat absorption plate is fixed outside the top end of the capillary copper pipe.

Preferably, the capillary copper tubes are arranged in the heat conducting plate in a plurality of groups, and the capillary copper tubes in the plurality of groups are distributed in the heat conducting plate at equal intervals.

Preferably, the bottom of the two sides of the radiating fins is provided with a splicing structure, the splicing structure comprises a clamping block, a reed and a clamping groove, the reed is fixed at the bottom of the two sides of the radiating fins, the clamping block is fixed at the bottom of the reed, and the clamping groove is formed in one side of the clamping block.

Preferably, the clamping blocks form a clamping structure with the heat conducting plate through the clamping grooves, and the clamping blocks are symmetrically distributed on the vertical central line of the heat radiating fins.

(III) advantageous effects

Compared with the prior art, the beneficial effects of the utility model are that: this G basic station is with cuting straightly formula aluminum alloy fin convenient to installation has not only realized quick installation, has realized accelerating thermal transmission, has realized heat radiation fins's quick concatenation moreover:

(1) the pressing plate is driven to move upwards by pulling the pull handle, meanwhile, the telescopic spring is stressed to contract, then the heat conducting plate is moved to the bottom end of the pressing plate, the telescopic spring pushes the pressing plate to move downwards by loosening the pull handle, the heat conducting plate is pushed to be tightly attached to the surface of the base station shell for heat dissipation, the fixing block is clamped into the pressing plate, the heat conducting plate is prevented from sliding to one side, and therefore the quick installation function of the device is achieved, the quick installation of the device is facilitated, and the working efficiency is improved;

(2) the heat transfer is accelerated through the excellent heat conductivity of the graphite sheet, the cooling liquid in the capillary copper tube is heated at the same time, the temperature of the cooling liquid is increased, the cooling liquid in the capillary copper tube circularly flows to accelerate heat conduction through the principle of expansion with heat and contraction with cold, and the heat is uniformly transferred to the inside of the heat conducting plate through the heat absorbing plate to dissipate heat, so that the function of accelerating the heat transfer of the device is realized, and the heat dissipation of the device is accelerated;

(3) the heat dissipation fins are pressed downwards, the inner wall of the slot extrudes the clamping block to enable the spring plate to bend towards the inside of the heat dissipation fins, the spring plate performs reset motion to drive the clamping block to rotate, the clamping block is clamped into the clamping groove, and the heat conduction plate and the heat dissipation fins are connected and fixed, so that the quick splicing function of the heat dissipation fins of the device is realized.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic three-dimensional structure of the present invention;

fig. 2 is a schematic front view of the cross-sectional structure of the present invention;

fig. 3 is a schematic view of the front cross-sectional structure of the mounting structure of the present invention;

fig. 4 is a schematic side view of a cross-sectional structure of the heat conducting structure of the present invention;

fig. 5 is an enlarged partial cross-sectional view of the point a in fig. 2 according to the present invention.

The reference numerals in the figures illustrate: 1. a heat conducting plate; 2. a fixing plate; 3. a mounting structure; 301. a connecting rod; 302. pulling a handle; 303. a tension spring; 304. pressing a plate; 305. a fixed block; 4. heat dissipation fins; 5. a base station housing; 6. silicone grease; 7. a heat conducting structure; 701. a heat absorbing plate; 702. cooling liquid; 703. a capillary copper tube; 704. a graphite sheet; 8. splicing structures; 801. a clamping block; 802. a reed; 803. a card slot; 9. and (4) a slot.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. Based on the embodiments of the present invention, all other embodiments obtained by a person of ordinary skill in the art without creative efforts belong to the protection scope of the present invention.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Referring to fig. 1-5, the present invention provides an embodiment: a direct-insert aluminum alloy radiating fin convenient to mount for a 5G base station comprises a heat conducting plate 1, a fixing plate 2 and radiating fins 4, wherein the top end of the heat conducting plate 1 is provided with a slot 9, the radiating fins 4 are arranged inside the slot 9, the bottom end of the heat conducting plate 1 is coated with silicone grease 6, the fixing plate 2 is arranged on two sides of the heat conducting plate 1, the bottom end of the fixing plate 2 is fixed with a base station shell 5, one side of the top end of the fixing plate 2 is provided with a mounting structure 3, the mounting structure 3 comprises a connecting rod 301, a pull handle 302, a telescopic spring 303, a pressing plate 304 and a fixing block 305, the connecting rod 301 is inserted into the top end of the fixing plate 2, the top end of the connecting rod 301 is fixed with the pull handle 302, the bottom end of the connecting rod 301 is fixed with the pressing plate 304, the outer side of the connecting rod 301 is sleeved with the telescopic spring 303, the fixing block 305 is arranged inside the bottom end of the pressing plate 304, the connecting rod 301 extends to the top end of the fixing plate 2 and is connected with the pull handle 302, the connecting rod 301 is driven to move upwards by pulling the pull handle 302, and a welding integrated structure is formed between the fixing block 305 and the heat conducting plate 1, so that the connection between the fixing block 305 and the pressing plate 304 is stable, and the pressing plate 304 is prevented from pushing the heat conducting plate 1 to enable the heat conducting plate 1 to slide;

specifically, as shown in fig. 1, 2 and 3, when the structure is used, the handle 302 is pulled upwards, the handle 302 drives the pressing plate 304 to move upwards through the connecting rod 301, the telescopic spring 303 is stressed to contract, then the heat conducting plate 1 is moved to the bottom end of the pressing plate 304, the fixing block 305 is aligned with the pressing plate 304, the telescopic spring 303 is reset by loosening the handle 302, the pressing plate 304 is pushed to move downwards, the pressing plate 304 pushes the heat conducting plate 1 to be tightly attached to the surface of the base station shell 5 for heat dissipation, and the fixing block 305 is clamped into the pressing plate 304 to prevent the heat conducting plate 1 from sliding to one side;

a heat conducting structure 7 is arranged in the bottom end of the heat conducting plate 1, the heat conducting structure 7 comprises a heat absorbing plate 701, cooling liquid 702, a capillary copper pipe 703 and a graphite sheet 704, the graphite sheet 704 is fixed in the bottom end of the heat conducting plate 1, the capillary copper pipe 703 is inserted in the graphite sheet 704, the cooling liquid 702 is arranged in the capillary copper pipe 703, the heat absorbing plate 701 is fixed on the outer side of the top end of the capillary copper pipe 703, a plurality of groups of capillary copper pipes 703 are arranged in the heat conducting plate 1, and the groups of capillary copper pipes 703 are distributed in the heat conducting plate 1 at equal intervals, so that heat conduction in the heat conducting plate 1 is facilitated, and uniform heat transfer is realized;

specifically, as shown in fig. 1, 2 and 4, when this structure is used, heat inside the base station enclosure 5 is conducted out by the contact between the graphite sheet 704 and the silicone grease 6, the heat transfer is accelerated by the excellent thermal conductivity of the graphite sheet 704, and at the same time, the graphite sheet 704 heats the cooling liquid 702 inside the capillary copper tube 703 to raise the temperature of the cooling liquid 702, and by the principle of expansion with heat and contraction with cold, the heated cooling liquid 702 flows upward to introduce heat into the inside of the heat absorbing plate 701, and at the same time, the cooling liquid 702 with low temperature flows into the graphite sheet 704 to absorb heat, so that the cooling liquid 702 inside the capillary copper tube 703 flows circularly to accelerate heat transfer, and heat is dissipated by the heat absorbing plate 701 through uniform heat transfer to the inside of the heat conducting plate 1;

the bottom ends of two sides of the heat dissipation fin 4 are provided with splicing structures 8, each splicing structure 8 comprises a fixture block 801, a spring plate 802 and a clamping groove 803, the spring plates 802 are fixed at the bottom ends of the inner parts of two sides of the heat dissipation fin 4, the fixture blocks 801 are fixed at the bottom ends of the spring plates 802, the clamping grooves 803 are formed in one sides of the fixture blocks 801, the fixture blocks 801 form clamping structures with the heat conduction plate 1 through the clamping grooves 803, the heat conduction plate 1 and the heat dissipation fin 4 are connected and fixed through the clamping grooves 803 in which the fixture blocks 801 are clamped, and the fixture blocks 801 are symmetrically distributed on the vertical central line of the heat dissipation fin 4, so that the fixture blocks 801 are fixed stably;

specifically, as shown in fig. 2 and 5, when the structure is used, the heat dissipating fin 4 is pressed downward, so that the inner wall of the slot 9 presses the fixture block 801 to cause the fixture block 801 to drive the spring plate 802 to bend toward the inside of the heat dissipating fin 4, and when the heat dissipating fin 4 moves to the bottom end of the slot 9, the bent spring plate 802 performs a return motion to drive the fixture block 801 to rotate, so that the fixture block 801 is clamped into the interior of the fixture block 803, and the heat conducting plate 1 is connected and fixed with the heat dissipating fin 4.

The working principle is as follows: the utility model discloses when using, at first, fix fixed plate 2 on the surface of base station shell 5, install the device, through upwards dragging pull 302, make pull 302 drive clamp plate 304 through connecting rod 301 and move upwards, simultaneously expanding spring 303 atress shrink, then move heat-conducting plate 1 to the bottom of clamp plate 304, make fixed block 305 aim at clamp plate 304, through loosening pull 302, make expanding spring 303 do the motion that resets, promote clamp plate 304 and move down, make clamp plate 304 promote heat-conducting plate 1 and hug closely the surface of base station shell 5 and dispel the heat, go into the inside of clamp plate 304 through fixed block 305 card, prevent that heat-conducting plate 1 from landing to one side, accomplish the quick installation to the device;

secondly, aligning and inserting the heat dissipation fin 4 into the slot 9, splicing the heat dissipation fin 4 and the heat conduction plate 1, pressing the heat dissipation fin 4 downwards to enable the inner wall of the slot 9 to extrude the fixture block 801 to cause the fixture block 801 to drive the reed 802 to bend towards the inside of the heat dissipation fin 4, when the heat dissipation fin 4 moves to the bottom end of the slot 9, performing reset motion through the bent reed 802 to drive the fixture block 801 to rotate, enabling the fixture block 801 to be clamped into the slot 803, and connecting and fixing the heat conduction plate 1 and the heat dissipation fin 4 to finish quick splicing of the device;

finally, when the device conducts heat, silicone grease 6 is coated on the surface of the heat conducting plate 1, so that the pores between the heat conducting plate 1 and the base station shell 5 are reduced, heat conduction is facilitated, heat inside the base station shell 5 is led out through the contact of the graphite sheet 704 and the silicone grease 6, the heat transfer is accelerated through the excellent heat conductivity of the graphite sheet 704, meanwhile, the graphite sheet 704 heats the cooling liquid 702 inside the capillary copper tube 703, the temperature of the cooling liquid 702 is raised, the heated cooling liquid 702 flows upwards to guide the heat into the heat absorbing plate 701 through the principle of thermal expansion and cold contraction, meanwhile, the low-temperature cooling liquid 702 flows into the graphite sheet 704 to absorb heat, the cooling liquid 702 inside the capillary copper tube 703 circularly flows to accelerate heat conduction, the heat is uniformly transferred to the inside of the heat conducting plate 1 through the heat absorbing plate 701 to dissipate the heat, the heat transfer of the accelerating device is completed, the contact area between the heat conducting plate 1 and the air is increased through the heat dissipating fins 4, the heat dissipation is accelerated, and the use work of the direct-insertion type aluminum alloy radiating fin for the 5G base station is finally completed.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

The above-described embodiments of the apparatus are merely illustrative, and the units described as separate parts may or may not be physically separate, and the parts displayed as units may or may not be physical units, may be located in one place, or may be distributed on a plurality of network units. Some or all of the modules may be selected according to actual needs to achieve the purpose of the solution of the present embodiment. One of ordinary skill in the art can understand and implement it without inventive effort.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention in its corresponding aspects.

Claims (7)

1. The utility model provides a 5G basic station is with cuting straightly formula aluminum alloy fin convenient to installation, includes heat-conducting plate (1), fixed plate (2) and radiating fin (4), its characterized in that: slots (9) are formed in the top ends of the heat conducting plates (1), heat radiating fins (4) are arranged inside the slots (9), silicone grease (6) is coated on the bottom ends of the heat conducting plates (1), and fixing plates (2) are arranged on two sides of the heat conducting plates (1);

the bottom mounting of fixed plate (2) has base station shell (5), one side on fixed plate (2) top sets up mounting structure (3), mounting structure (3) include connecting rod (301), draw handle (302), expanding spring (303), clamp plate (304) and fixed block (305), the inside on fixed plate (2) top is inserted in connecting rod (301), the top of connecting rod (301) is fixed with and draws handle (302).

2. An easy-to-install 5G in-line aluminum alloy heat sink for base station as claimed in claim 1, wherein: the bottom end of the connecting rod (301) is fixed with a pressing plate (304), the outer side of the connecting rod (301) is sleeved with a telescopic spring (303), and a fixing block (305) is arranged inside the bottom end of the pressing plate (304).

3. An easy-to-install 5G in-line aluminum alloy heat sink for base station as claimed in claim 1, wherein: the connecting rod (301) extends to the top end of the fixing plate (2) and is connected with the pull handle (302), and a welding integrated structure is formed between the fixing block (305) and the heat conducting plate (1).

4. An easy-to-install 5G in-line aluminum alloy heat sink for base station as claimed in claim 1, wherein: the heat conduction plate is characterized in that a heat conduction structure (7) is arranged inside the bottom end of the heat conduction plate (1), the heat conduction structure (7) comprises a heat absorption plate (701), cooling liquid (702), a capillary copper pipe (703) and a graphite sheet (704), the graphite sheet (704) is fixed inside the bottom end of the heat conduction plate (1), the capillary copper pipe (703) is inserted into the graphite sheet (704), the cooling liquid (702) is arranged inside the capillary copper pipe (703), and the heat absorption plate (701) is fixed outside the top end of the capillary copper pipe (703).

5. An easy-to-install 5G in-line aluminum alloy heat sink for base station as claimed in claim 4, wherein: the capillary tubes (703) are arranged in the heat conducting plate (1) in a plurality of groups, and the capillary tubes (703) in the heat conducting plate (1) are distributed at equal intervals.

6. An easy-to-install 5G in-line aluminum alloy heat sink for base station as claimed in claim 1, wherein: the bottom of cooling fin (4) both sides is provided with mosaic structure (8), mosaic structure (8) include fixture block (801), reed (802) and draw-in groove (803), the inside bottom in cooling fin (4) both sides is fixed in reed (802), the bottom mounting of reed (802) has fixture block (801), and draw-in groove (803) have been seted up to one side of fixture block (801).

7. An easy-to-install 5G in-line aluminum alloy heat sink for base station as claimed in claim 6, wherein: the clamping blocks (801) form a clamping structure with the heat conducting plate (1) through the clamping grooves (803), and the clamping blocks (801) are symmetrically distributed on the vertical central line of the heat radiating fins (4).

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