CN217252660U - Up-drawing continuous casting impregnated copper rod leading-in device capable of rapidly dissipating heat - Google Patents

Abstract

The utility model discloses a rapid heat dissipation continuous casting impregnated copper rod guiding device in the technical field of upward casting machines, which comprises a shell, wherein a cold material pipe is arranged in the middle of the shell, a left heat conducting strip is arranged on the left side of the cold material pipe, a first heat dissipation device is arranged on the left side of the left heat conducting strip, a right heat conducting strip is arranged on the right side of the cold material pipe, a second heat dissipation device is arranged on the right side of the right heat conducting strip, the second heat dissipation device comprises a shell, a cold-heat exchanger is arranged at the top in the shell, a circulating pump is arranged on the right side of the bottom of the cold-heat exchanger, a water outlet pipe is arranged on the bottom of the circulating pump, a water tank is arranged on the left side of the bottom of the cold-heat exchanger, a connecting pipe is arranged on the bottom of the water tank, a water inlet pipe is arranged on the bottom of the connecting pipe, a heat dissipation pipe is arranged on the surface of the right side of the water inlet pipe, and heat dissipation is carried out by using cooling liquid, the quick pipe that dispels the heat to cold burden, effectively improves the radiating efficiency.

Description

Up-drawing continuous casting impregnated copper rod leading-in device capable of rapidly dissipating heat

Technical Field

The utility model relates to an upward draw conticaster technical field, specifically be a can quick radiating upward draw continuous casting flooding copper pole gatherer.

Background

The continuous casting machine is indispensable equipment in the continuous casting process, and in the production process of the last initiation, the crystallizer is mainly utilized to cool the liquid copper in the holding furnace fast, and the cooling mode is adopted to cool off to current crystallizer, and cooling efficiency is low, influences the speed that liquid copper solidifies into solid-state greatly, and then leads to the reduction of the production efficiency of conticaster. Therefore, the device for guiding the upward continuous casting impregnated copper rod can quickly dissipate heat.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a can draw continuous casting flooding copper pole gatherer fast radiating to solve the problem that provides in the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: a quick-radiating up-drawing continuous-casting impregnated copper rod guiding device comprises a shell, wherein a cold material pipe is arranged in the middle of the shell, a left heat conducting sheet is arranged on the left side of the cold material pipe, a first radiating device is arranged on the left side of the left heat conducting sheet, a right heat conducting sheet is arranged on the right side of the cold material pipe, a second radiating device is arranged on the right side of the right heat conducting sheet, the second radiating device comprises a shell, a cold-heat exchanger is arranged at the top in the shell, a circulating pump is arranged on the right side of the bottom of the cold-heat exchanger, a water outlet pipe is arranged at the bottom of the circulating pump, a right through hole is formed in the lower part of the right surface of the shell, a first radiating fan is arranged in the right through hole, a water tank is arranged on the left side of the bottom of the cold-heat exchanger, a connecting pipe is arranged at the bottom of the water tank, a water inlet pipe is arranged at the bottom of the connecting pipe, and a radiating pipe is arranged on the right surface of the water inlet pipe, the upper and lower both sides of cooling tube all are provided with the fin, the left side surface lower part of shell is provided with left opening, be provided with second radiator fan in the opening of a left side.

Preferably, the left and right sides surface of cooling tube all is provided with the arch, the surface that fin and cooling tube contacted all is provided with the recess with protruding matched with.

Preferably, the cold-heat exchanger and the circulating pump are connected with the circulating pump and the water outlet pipe through connecting pipes.

Preferably, the cold-heat exchanger is connected with the water tank through a water pipe, the bottom of the water pipe extends into the bottom of the water tank, and the top of the connecting pipe is below the liquid level of the cooling liquid in the water tank.

Preferably, the radiating fins and the radiating pipe are arranged at intervals, and the rear ends of the radiating fins are in contact with the surface of the right heat conducting fin.

Preferably, the first cooling fan installed in the left opening and the second cooling fan installed in the left opening are both provided with two sets.

Compared with the prior art, the beneficial effects of the utility model are that: the circulating pump is at the rotation in-process, the coolant liquid in the water tank enters into the outlet pipe through the connecting pipe, the coolant liquid enters into the outlet pipe through the cooling tube, the coolant liquid is when through the cooling tube, give away the heat of cooling tube with the fin transmission, the completion is to fin and left conducting strip and the heat dissipation of right conducting strip, thereby dispel the heat to cold burden pipe, the coolant liquid is in dislike circulating pump entering cold heat exchanger through the outlet pipe, enter into the water tank at last, accomplish a circulation, effectual saving coolant liquid, dispel the heat through using the coolant liquid, it dispels the heat to cold burden pipe fast, effectively improve the radiating efficiency.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a side view of the structure of the present invention;

FIG. 3 is a schematic view of the heat dissipation device of the present invention;

fig. 4 is a schematic view of the connection structure of the heat dissipation tube and the heat dissipation fin of the present invention.

In the figure: 1. a housing; 2. a cold material pipe; 3. a left thermally conductive sheet; 4. a first heat sink; 5. a right heat-conducting fin; 6. a second heat sink; 7. a housing; 8. a cold-heat exchanger; 9. a circulation pump; 10. a water outlet pipe; 11. a right through hole; 12. a first heat dissipation fan; 13. a water tank; 14. a connecting pipe; 15. a water inlet pipe; 16. a radiating pipe; 161. a protrusion; 17. a heat sink; 171. a groove; 18. a left port; 19. a second heat dissipation fan.

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 in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-4, the present invention provides a technical solution: a quick-radiating up-drawing continuous-casting impregnated copper rod guiding device comprises a shell 1, a cold material pipe 2 is arranged in the middle of the shell 1, a left heat conducting fin 3 is arranged on the left side of the cold material pipe 2, a first heat radiating device 4 is arranged on the left side of the left heat conducting fin 3, a right heat conducting fin 5 is arranged on the right side of the cold material pipe 2, a second heat radiating device 6 is arranged on the right side of the right heat conducting fin 5, the second heat radiating device 6 comprises a shell 7, a cold-heat exchanger 8 is arranged at the top in the shell 7, a circulating pump 9 is arranged on the right side of the bottom of the cold-heat exchanger 8, a water outlet pipe 10 is arranged at the bottom of the circulating pump 9, a right through hole 11 is arranged at the lower part of the right surface of the shell 7, a first radiating fan 12 is arranged in the right through hole 11, a water tank 13 is arranged on the left side of the bottom of the cold-heat exchanger 8, a connecting pipe 14 is provided with a connecting pipe 15, a radiating pipe 16 is arranged on the right surface of the connecting pipe 14, the upper and lower sides of the radiating pipe 16 are provided with radiating fins 17, the lower part of the left side surface of the shell 7 is provided with a left through hole 18, a second radiating fan 19 is arranged in the left through hole 18, when the first radiating device 4 and the second radiating device 6 radiate the cold material pipe 2, the cold material pipe 2 transmits heat to the first radiating device 4 and the second radiating device 6 through the left heat conducting fin 3 and the right heat conducting fin 5, the left heat conducting fin 3 and the right heat conducting fin 5 transmit heat to the radiating fins 17, the circulating pump 9 is started, the cooling liquid in the water tank 13 enters the water inlet pipe 15 through the connecting pipe 14 during the rotation process, the cooling liquid enters the water outlet pipe 10 through the radiating pipe 16, the cooling liquid takes away the heat transmitted to the radiating pipe 16 by the radiating fins 17 when passing through the radiating pipe 16, the heat radiation to the radiating fins 17 and the left heat conducting fin 3 and the right heat conducting fin 5 is completed, thereby radiating the cold material pipe, the cooling liquid enters the cold-heat exchanger 8 through the water outlet pipe 10 and the circulating pump 9, and finally enters the water tank 13 to complete a cycle.

Wherein, the left and right surfaces of the radiating pipe 16 are provided with protrusions 161, the surfaces of the radiating fins 17 contacting the radiating pipe 16 are provided with grooves 171 matching with the protrusions 161, the contact area between the radiating pipe 16 and the radiating fins 17 is increased, and thus the heat emitted by the radiating fins 17 is taken away quickly;

the cold-heat exchanger 8 and the circulating pump 9 are connected with the circulating pump 9 and the water outlet pipe 10 through connecting pipes, the cold-heat exchanger 8 is connected with the water tank 13 through a water pipe, the bottom of the water pipe extends into the bottom of the water tank 13, and the top of the connecting pipe 14 is below the liquid level of the cooling liquid in the water tank 13;

the radiating fins 17 and the radiating pipes 16 are arranged at intervals, the rear ends of the radiating fins 17 are in contact with the surface of the right heat conducting fin 5, the radiating fins 17 transmit the right heat conducting fin 5 to radiate the radiating fins 17 through the radiating pipes 16, and therefore the radiating of the right heat conducting fin 5 is completed;

first radiator fan 12 of installation in the opening 11 of the right side and the second radiator fan 19 of installation in the opening 18 of the left side all are provided with two sets ofly, can accelerate the completion through two sets of first radiator fan 12 and two sets of second radiator fan 19 and to the heat dissipation of cold material pipe 2.

The working principle is as follows: the heat is transmitted to the radiating fin 17 by the left heat-conducting fin 3 and the right heat-conducting fin 5, the circulating pump 9 is started, the circulating pump 9 is in the rotating process, the cooling liquid in the water tank 13 enters the water inlet pipe 15 through the connecting pipe 14, the cooling liquid enters the water outlet pipe 10 through the radiating pipe 16, the cooling liquid takes away the heat transmitted to the radiating fin 17 to the radiating pipe 16 when passing through the radiating pipe 16, the left side surface and the right side surface of the radiating pipe 16 are provided with the bulges 161, the surface of the radiating fin 17 contacted with the radiating pipe 16 is provided with the grooves 171 matched with the bulges 161, the contact area of the radiating fin 16 and the radiating fin 17 is increased, thereby the heat emitted by the radiating fin 17 is taken away quickly, the heat radiation to the radiating fin 17, the left heat-conducting fin 3 and the right heat-conducting fin 5 is completed, the heat radiation to the cold material pipe is performed, the cooling liquid enters the cold heat exchanger 8 through the water outlet pipe 10 and the circulating pump 9, and finally enters the water tank 13, one cycle is completed.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a but quick radiating draw-in continuous casting flooding copper pole gatherer, includes casing (1), its characterized in that: the middle of the shell (1) is provided with a cold material pipe (2), the left side of the cold material pipe (2) is provided with a left heat conducting fin (3), the left side of the left heat conducting fin (3) is provided with a first heat radiating device (4), the right side of the cold material pipe (2) is provided with a right heat conducting fin (5), the right side of the right heat conducting fin (5) is provided with a second heat radiating device (6), the second heat radiating device (6) comprises a shell (7), the top in the shell (7) is provided with a cold-heat exchanger (8), the right side of the bottom of the cold-heat exchanger (8) is provided with a circulating pump (9), the bottom of the circulating pump (9) is provided with a water outlet pipe (10), the lower part of the right side surface of the shell (7) is provided with a right through hole (11), the right through hole (11) is internally provided with a first heat radiating fan (12), the left side of the bottom of the cold-heat exchanger (8) is provided with a water tank (13), the bottom of water tank (13) is provided with connecting pipe (14), the bottom of connecting pipe (14) is provided with inlet tube (15), the right side surface of inlet tube (15) is provided with cooling tube (16), the upper and lower both sides of cooling tube (16) all are provided with fin (17), the left side surface lower part of shell (7) is provided with left opening (18), be provided with second radiator fan (19) in left side opening (18).

2. The lead-in device of the upward continuous casting impregnated copper rod capable of rapidly dissipating heat according to claim 1, characterized in that: the left and right side surfaces of the radiating pipe (16) are provided with protrusions (161), and the surfaces of the radiating fins (17) contacted with the radiating pipe (16) are provided with grooves (171) matched with the protrusions (161).

3. The lead-in device of the upward continuous casting impregnated copper rod capable of rapidly dissipating heat according to claim 1, characterized in that: the cold-heat exchanger (8) and the circulating pump (9) are connected with the circulating pump (9) and the water outlet pipe (10) through connecting pipes.

4. The lead-in device of the upward continuous casting impregnated copper rod capable of rapidly dissipating heat according to claim 1, characterized in that: the cold-heat exchanger (8) is connected with the water tank (13) through a water pipe, the bottom of the water pipe extends into the bottom of the water tank (13), and the top of the connecting pipe (14) is arranged below the liquid level of cooling liquid in the water tank (13).

5. The lead-in device of the upward continuous casting impregnated copper rod capable of rapidly dissipating heat according to claim 1, characterized in that: the radiating fins (17) and the radiating pipe (16) are installed at intervals, and the rear ends of the radiating fins (17) are in contact with the surface of the right heat conducting fin (5).

6. The lead-in device for the upward continuous casting impregnated copper rod capable of rapidly dissipating heat as claimed in claim 1, wherein: and two groups of first cooling fans (12) arranged in the right through hole (11) and two groups of second cooling fans (19) arranged in the left through hole (18) are arranged.

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