CN216010776U

CN216010776U - Nano-fluid superconducting radiator

Info

Publication number: CN216010776U
Application number: CN202122755512.7U
Authority: CN
Inventors: 罗延旭; 王亚辉; 刘耀; 李威; 史伟; 刘霜; 刘振
Original assignee: Inner Mongolia University of Technology
Current assignee: Inner Mongolia University of Technology
Priority date: 2021-11-11
Filing date: 2021-11-11
Publication date: 2022-03-11
Anticipated expiration: 2031-11-11

Abstract

The utility model discloses a nanometer fluid superconductive radiator, including heat dissipation casing and pump storehouse, rigid coupling has the heat-absorbing pipe in the heat dissipation casing, the pump storehouse is established at the rear side of heat dissipation casing, the top of heat-absorbing pipe is connected through first cooling tube with the pump storehouse, the bottom of heat-absorbing pipe is connected through the second cooling tube with the pump storehouse, contain nanometer fluid superconductive medium in heat-absorbing pipe, pump storehouse, first cooling tube and the second cooling tube, still include the motor, motor drive has the fan blade group, the utility model has the beneficial effects that, through the motor produces power, the pump storehouse makes nanometer fluid superconductive medium flow in heat-absorbing pipe, pump storehouse, first cooling tube and second cooling tube, when flowing through the heat-absorbing pipe position, absorbs the heat in the heat dissipation casing, when passing through first cooling tube and cooling tube position, makes the fan blade group rotate through the motor to make the air flow speed of first cooling tube and second cooling tube position accelerate, the heat dissipation effect is improved.

Description

Nano-fluid superconducting radiator

Technical Field

The utility model relates to a radiator technical field, concretely relates to nanofluid superconductive radiator.

Background

For a large-scale integrated combined LED lamp, the heat dissipation problem is outstanding, and because the aluminum alloy is cheap, the quality is light and has good heat conductivity, a common practical aluminum alloy shell is used as a radiator of the LED, but the power of the large-scale integrated combined LED lamp is large when the large-scale integrated combined LED lamp works, so that the generated heat is more, the heat can be dissipated only by depending on an aluminum alloy shell, the heat cannot be dissipated out in time, the heat accumulation is caused, the aging speed of an electrical appliance is accelerated, and the risk of fire hazard can be generated.

SUMMERY OF THE UTILITY MODEL

In order to solve the above problems, the utility model provides a nanofluid superconducting radiator, which is realized by the following technical scheme.

A nanofluid superconducting radiator comprises a radiating shell and a pump chamber; the horizontal even rigid coupling has the heat absorption pipe between the roof of heat dissipation casing and the bottom plate, the pump storehouse sets up the rear side at the heat dissipation casing, and the pump storehouse passes through backup pad and heat dissipation casing fixed connection, the top rigid coupling of heat absorption pipe has first cooling tube, the head of first cooling tube is connected with the posterior lateral plate middle part in pump storehouse, and the bottom rigid coupling of heat absorption pipe has the second cooling tube, the head of second cooling tube is connected with the anterior lateral plate middle part in pump storehouse, and the splendid attire has nanometer fluid superconducting medium in heat absorption pipe, pump storehouse, first cooling tube and the second cooling tube, and the rigid coupling has the mounting box on the anterior lateral plate of heat dissipation casing, be used for installing the LED lamp plate in the mounting box.

Furthermore, the heat dissipation shell between the adjacent heat absorption pipes is provided with a groove on the front side plate, the bottom of each groove is vertically and evenly provided with a mounting groove, the mounting box is fixedly connected in the mounting groove, and the heat dissipation shell further comprises a transparent cover plate, and the transparent cover plate is glued in the grooves.

Furthermore, the outer wall of the front side plate of the heat dissipation shell is fixedly connected with heat dissipation fins, the rear ends of the heat dissipation fins extend into the heat dissipation shell, and the heat dissipation fins and the grooves are arranged in a staggered mode.

Furthermore, communicating pipes are symmetrically and fixedly connected to the left side plate and the right side plate of each mounting box, the head of each communicating pipe is connected with the corresponding heat absorbing pipe, and a heat conducting pipe is arranged between the communicating pipes in a butterfly shape.

Further, the mounting box is filled with heat conduction silica gel, heat conduction silica gel covers the heat pipe therein, the LED lamp plate is installed on heat conduction silica gel.

Further, the right side rigid coupling has the motor in the backup pad, the motor is equipped with the output shaft that the level was left, the left end of output shaft is rotated and is connected in left backup pad, and it has the worm to follow the even rigid coupling of its length direction on the output shaft, rotates on the heat dissipation casing posterior lateral plate of both sides about each worm and is connected with first pivot, the head rigid coupling of first pivot has the worm wheel with worm meshing, and it has the driving gear still to rigid coupling in the first pivot of each worm wheel front side, rotates on the heat dissipation casing posterior lateral plate in each driving gear outside and is connected with the second pivot, the rigid coupling has the driven gear with driving gear meshing in the second pivot, and it has the flabellum seat to still rigid coupling in the second pivot, and the even rigid coupling of the outer lane circumference of each flabellum seat has the flabellum group.

Furthermore, heat dissipation fences are fixedly connected between the first heat dissipation pipes and between the second heat dissipation pipes.

Further, a liquid outlet joint and a liquid inlet joint are fixedly connected to the middle of the front side plate and the rear side plate of the pump chamber respectively, the head of the first radiating pipe is connected with the liquid inlet joint, the head of the second radiating pipe is connected with the liquid outlet joint, a first one-way valve and a second one-way valve are arranged in the liquid outlet joint and the liquid inlet joint respectively, the direction in which the first one-way valve allows fluid to pass through is the direction departing from the inner cavity of the pump chamber, the direction in which the second one-way valve allows fluid to pass through is the direction pointing to the inner cavity of the pump chamber, two piston plates are slidably connected in the pump chamber, the two piston plates are symmetrically arranged up and down, one sides of the piston plates, which are far away from each other, are fixedly connected with rotary seats, the rotary seats on the upper side plate and the lower side plate of the pump chamber are slidably connected in the upper side plate and the lower side plate of the pump chamber respectively, vent holes are further formed in the upper side plate and the lower side plate are fixedly connected with disks, the rotary seats on the upper side and the lower side plate respectively correspond to the disks on the upper side and the lower side plate, the surface of the disc is eccentrically hinged with a connecting rod, and the other end of the connecting rod is hinged with a corresponding rotary seat.

The beneficial effects of the utility model are that, produce power through the motor, the pump storehouse makes the superconductive medium of nanometer fluid flow in heat-absorbing pipe, pump storehouse, first cooling tube and second cooling tube, when flowing through the heat-absorbing pipe position, absorbs the heat in the radiating shell, when first cooling tube and cooling tube position, makes the rotation of fan blade group through the motor to make the air flow speed of first cooling tube and second cooling tube position accelerate, improve radiating effect.

Drawings

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

FIG. 1: the utility model discloses a three-dimensional schematic diagram of a nanofluid superconducting radiator;

FIG. 2: the utility model discloses a three-dimensional schematic diagram of another angle of the nanofluid superconducting radiator;

FIG. 3: the utility model discloses a sectional view of a nanofluid superconducting radiator;

FIG. 4: FIG. 3 is a partial enlarged view of the point A;

FIG. 5: the utility model is a cross section of the pump chamber;

FIG. 6: the utility model discloses a driving schematic diagram of a fan blade group;

FIG. 7: the internal structure of the heat dissipation shell of the utility model is shown schematically;

FIG. 8: the structure schematic diagram of the front side plate of the heat dissipation shell of the utility model;

FIG. 9: the internal structure schematic diagram of mounting box.

The reference numbers are as follows:

1-radiating shell, 2-pump bin, 3-heat absorbing pipe, 4-support plate, 5-first radiating pipe, 6-second radiating pipe, 7-mounting box, 8-LED lamp panel, 9-groove, 10-mounting groove, 11-transparent cover plate, 12-radiating fin, 13-communicating pipe, 14-heat conducting pipe, 15-heat conducting silica gel, 16-motor, 17-output shaft, 18-worm, 19-first rotating shaft, 20-worm wheel, 21-driving gear, 22-second rotating shaft, 23-driven gear, 24-vane seat, 25-vane group, 26-radiating fence, 27-liquid outlet joint, 28-liquid inlet joint, 29-first one-way valve, 30-second one-way valve, 31-piston plate, 32-rotation seat, 33-ventilation hole, 34-disc and 35-connecting rod.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. 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.

As shown in fig. 1-9, a nanofluid superconducting radiator comprises a radiating shell 1 and a pump chamber 2; horizontal even rigid coupling has heat-absorbing pipe 3 between the roof of heat dissipation casing 1 and the bottom plate, pump storehouse 2 sets up the rear side at heat dissipation casing 1, pump storehouse 2 is through

backup pad

4 and 1 fixed connection of heat dissipation casing, the top rigid coupling of heat-absorbing pipe 3 has first cooling tube 5, the head of first cooling tube 5 is connected with the posterior lateral plate middle part of pump storehouse 2, the bottom rigid coupling of heat-absorbing pipe 3 has second cooling tube 6, the head of second cooling tube 6 is connected with the preceding lateral plate middle part of pump storehouse 2, heat-absorbing pipe 3, pump storehouse 2, splendid attire nanometer fluid superconducting medium has in first cooling tube 5 and the second cooling tube 6, the rigid coupling has mounting box 7 on the preceding lateral plate of heat dissipation casing 1, the internal LED lamp plate 8 that is used for installing of mounting box 7.

Preferably, the front side plate of the heat dissipation shell 1 between the adjacent heat absorption tubes 3 is provided with grooves 9, the bottom of each groove 9 is vertically and uniformly provided with a mounting groove 10, the mounting box 7 is fixedly connected in the mounting groove 10, and the heat dissipation shell further comprises a transparent cover plate 11, and the transparent cover plate 11 is glued in the grooves 9.

Preferably, the outer wall of the front side plate of the heat dissipation housing 1 is further fixedly connected with heat dissipation fins 12, the rear ends of the heat dissipation fins 12 extend into the heat dissipation housing 1, and the heat dissipation fins 12 and the grooves 9 are arranged in a staggered manner.

Preferably, the left and right side plates of each mounting box 7 are symmetrically and fixedly connected with communication pipes 13, the head of each communication pipe 13 is connected with the corresponding heat absorption pipe 3, and a heat conduction pipe 14 is arranged between the communication pipes 13 in a butterfly shape.

Preferably, the installation box 7 is filled with heat conduction silica gel 15, the heat conduction silica gel 15 covers the heat conduction pipe 14 therein, and the LED lamp panel 8 is installed on the heat conduction silica gel 15.

Preferably, a motor 16 is fixedly connected in the right support plate 4, the motor 16 is provided with a horizontal leftward output shaft 17, the left end of the output shaft 17 is rotatably connected in the left support plate 4, worms 18 are uniformly and fixedly connected on the output shaft 17 along the length direction thereof, first rotating shafts 19 are rotatably connected on the rear side plates of the heat dissipation shell 1 on the upper side and the lower side of each worm 18, the head of each first rotating shaft 19 is fixedly connected with a worm wheel 20 meshed with the worm 18, a driving gear 21 is further fixedly connected on the first rotating shaft 19 on the front side of each worm wheel 20, a second rotating shaft 22 is rotatably connected on the rear side plate of the heat dissipation shell 1 on the outer side of each driving gear 21, a driven gear 23 meshed with the driving gear 21 is fixedly connected on the second rotating shaft 22, a fan blade seat 24 is further fixedly connected on the second rotating shaft 22, and a fan blade group 25 is uniformly and fixedly connected on the circumference of the outer ring of each fan blade seat 24.

Preferably, heat dissipation barriers 26 are fixedly connected between the first heat dissipation pipes 5 and between the second heat dissipation pipes 6.

Preferably, the middle parts of the front and rear side plates of the pump chamber 2 are respectively fixedly connected with a liquid outlet joint 27 and a liquid inlet joint 28, the head part of the first radiating pipe 5 is connected with the liquid inlet joint 28, the head part of the second radiating pipe 6 is connected with the liquid outlet joint 27, the liquid outlet joint 27 and the liquid inlet joint 28 are respectively provided with a first one-way valve 29 and a second one-way valve 30, the direction that the first one-way valve 29 allows fluid to pass through is the direction departing from the inner cavity of the pump chamber 2, the direction that the second one-way valve 30 allows fluid to pass through is the direction pointing to the inner cavity of the pump chamber 2, the pump chamber 2 is internally and slidably connected with a piston plate 31, the two piston plates 31 are vertically and symmetrically arranged, one sides of the piston plates 31, which are far away from each other, are respectively and slidably connected into the upper and lower side plates of the pump chamber 2, the upper and lower side plates of the pump chamber 2 are also provided with vent holes 33, the head parts of the second rotating shafts 22 are fixedly connected with a disc 34, the rotary bases 32 on the upper side and the lower side respectively correspond to the discs 34 on the upper side and the lower side, the surfaces of the discs 34 are eccentrically hinged with connecting rods 35, and the other ends of the connecting rods 35 are hinged with the corresponding rotary bases 32.

The utility model discloses a concrete implementation does:

during the use, install LED lamp plate 8 on the heat conduction silica gel 15 in each mounting box 7 at first, then with transparent cover 11 veneer in recess 9.

Each 8 during operation of LED lamp plates can dispel the heat through radiating fin 12, and the heat that 8 during operation of LED lamp plates produced absorbs through heat conduction silica gel 15, and under the heat conduction of superconducting medium effect, the heat transmits the outer wall of heat dissipation casing 1 through heat pipe 14, communicating pipe 13 and heat absorption pipe 3 to dispel the heat in

first cooling tube

5 and 6 positions of second cooling tube.

When the temperature is higher, the motor 16 can be turned on, the motor 16 drives the output shaft 17 and the worm 18 fixedly connected thereto to rotate when working, the worm 18 drives the worm wheel 20 to rotate, thereby the first rotating shaft 19 and the driving gear 21 rotate, the driven gear 23 engaged therewith rotates, further the second rotating shaft 22 and the fan blade set 25 rotate, when the fan blade set 25 rotates, the air flowing speed of the positions of the first radiating pipe 5 and the second radiating pipe 6 is accelerated, thereby the heat exchange speed of the first radiating pipe 5 and the second radiating pipe 6 with the external environment is increased, and the radiating effect is improved.

When the second rotating shaft 22 rotates, the disc 34 is also driven to rotate, and the disc 34 drives the rotary seat 32 and the piston plate 31 to lift and lower through the connecting rod 35 eccentrically hinged with the disc 34.

When the initial state is set, the two piston plates 31 are located at positions close to each other as shown in fig. 5, when the piston plates 31 are far away from each other, the superconducting medium in the first heat dissipation pipe 5 enters the pump chamber 2, otherwise, when the two piston plates 31 are far away from each other, the superconducting medium in the pump chamber 2 enters the second heat dissipation pipe 6, so that the superconducting medium is in a continuous flowing state, the heat exchange speed and effect are improved, and the heat dissipation effect of the heat sink is improved.

Through the arrangement of the heat dissipation fence 26, the heat exchange area is increased, and the heat dissipation effect is further improved.

The preferred embodiments of the present invention disclosed above are intended only to help illustrate the present invention. The preferred embodiments are not exhaustive and do not limit the invention to the precise embodiments disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and its practical applications, to thereby enable others skilled in the art to best understand the invention for and utilize the invention. The present invention is limited only by the claims and their full scope and equivalents.

Claims

1. A nanofluid superconducting radiator, characterized by: comprises a heat dissipation shell and a pump chamber; the horizontal even rigid coupling has the heat absorption pipe between the roof of heat dissipation casing and the bottom plate, the pump storehouse sets up the rear side at the heat dissipation casing, and the pump storehouse passes through backup pad and heat dissipation casing fixed connection, the top rigid coupling of heat absorption pipe has first cooling tube, the head of first cooling tube is connected with the posterior lateral plate middle part in pump storehouse, and the bottom rigid coupling of heat absorption pipe has the second cooling tube, the head of second cooling tube is connected with the anterior lateral plate middle part in pump storehouse, and the splendid attire has nanometer fluid superconducting medium in heat absorption pipe, pump storehouse, first cooling tube and the second cooling tube, and the rigid coupling has the mounting box on the anterior lateral plate of heat dissipation casing, be used for installing the LED lamp plate in the mounting box.

2. The nanofluid superconducting heat sink of claim 1, wherein: the heat dissipation shell comprises a heat absorption pipe and a mounting box, wherein the heat absorption pipe is arranged in the heat dissipation shell, the mounting box is fixedly connected with the mounting box, and the heat dissipation shell is provided with a groove on the front side plate between adjacent heat absorption pipes.

3. The nanofluid superconducting heat sink of claim 2, wherein: the outer wall of the front side plate of the radiating shell is further fixedly connected with radiating fins, the rear ends of the radiating fins extend into the radiating shell, and the radiating fins and the grooves are arranged in a staggered mode.

4. The nanofluid superconducting heat sink of claim 3, wherein: communicating pipes are symmetrically and fixedly connected to the left side plate and the right side plate of each mounting box, the head of each communicating pipe is connected with the corresponding heat absorbing pipe, and heat conducting pipes are arranged between the communicating pipes in a butterfly shape.

5. The nanofluid superconducting heat sink of claim 4, wherein: the LED lamp panel is characterized in that heat-conducting silica gel is filled in the mounting box, the heat-conducting silica gel covers the heat-conducting pipe, and the LED lamp panel is mounted on the heat-conducting silica gel.

6. The nanofluid superconducting heat sink of claim 1, wherein: the right side the rigid coupling has the motor in the backup pad, the motor is equipped with the output shaft that the level was left, the left end of output shaft is rotated and is connected in left backup pad, and it has the worm to rotate on the output shaft along the even rigid coupling of its length direction, rotates on the heat dissipation casing posterior lateral plate of both sides about each worm and is connected with first pivot, the head rigid coupling of first pivot has the worm wheel with worm meshing, and it has the driving gear still to rigid coupling in the first pivot of each worm wheel front side, rotates on the heat dissipation casing posterior lateral plate in each driving gear outside and is connected with the second pivot, the rigid coupling has the driven gear with driving gear meshing in the second pivot, and it has the flabellum seat to still rigid coupling in the second pivot, and the even rigid coupling of outer lane circumference of each flabellum seat has the flabellum group.

7. The nanofluid superconducting heat sink of claim 6, wherein: and heat dissipation fences are fixedly connected between the first heat dissipation pipes and between the second heat dissipation pipes.

8. The nanofluid superconducting heat sink of claim 6, wherein: the middle parts of the front side plate and the rear side plate of the pump bin are respectively fixedly connected with a liquid outlet joint and a liquid inlet joint, the head part of the first radiating pipe is connected with the liquid inlet joint, the head part of the second radiating pipe is connected with the liquid outlet joint, a first one-way valve and a second one-way valve are respectively arranged in the liquid outlet joint and the liquid inlet joint, the direction of allowing fluid to pass through by the first one-way valve is the direction departing from the inner cavity of the pump bin, the direction of allowing fluid to pass through by the second one-way valve is the direction pointing to the inner cavity of the pump bin, two piston plates are slidably connected in the pump bin, the two piston plates are vertically and symmetrically arranged, one sides of the piston plates, which are far away from each other, are fixedly connected with rotary seats, the rotary seats on the upper side plate and the lower side plate of the pump bin are respectively and slidably connected in the upper side plate and the lower side plate of the pump bin, air vents are also arranged on the upper side plate and the lower side plate, the heads of the second rotary shafts are fixedly connected with discs, the rotary seats on the upper side and the lower side plate are respectively corresponding to the discs on the upper side plate and the lower side plate, the surface of the disc is eccentrically hinged with a connecting rod, and the other end of the connecting rod is hinged with a corresponding rotary seat.