CN216461635U - High-efficient cooling system of zinc-aluminum-magnesium-boron alloy ingot large-scale production - Google Patents

Abstract

The utility model discloses a high-efficient cooling system of zinc-aluminium-magnesium-boron alloy ingot large-scale production relates to alloy production auxiliary assembly technical field. The utility model discloses a driving plate and be used for supporting the supporting leg of driving plate, driving plate top horizontal sliding installs places the board, place the standing groove that the board top evenly offered and is used for placing the mould, the driving plate bottom is installed and is used for radiating water-cooling component, install the support body that is located its top on the driving plate, the support body bottom is rotated through the pivot and is installed radiator fan, the support body top is installed and is acted on radiator fan's interlock subassembly works as when water-cooling component starts, through the interlock subassembly so that radiator fan rotates. The utility model discloses when water-cooling component starts, make radiator fan rotate through the interlock subassembly to realize melting the cooling of water to the alloy through water-cooling and forced air cooling, thereby further improved cooling rate, consequently more have the practicality.

Description

High-efficient cooling system of zinc-aluminum-magnesium-boron alloy ingot large-scale production

Technical Field

The utility model relates to an alloy production auxiliary assembly technical field, concretely relates to high-efficient cooling system of zinc-aluminium-magnesium-boron alloy ingot large-scale production.

Background

The zinc-aluminum-magnesium-boron alloy is used as a hot dipping raw material for the surface treatment of steel materials, can improve the surface appearance and the corrosion resistance of a plating layer, and is generally used at present. In the zinc-aluminum-magnesium-boron alloy smelting process, need to smelt metal into alloy molten water, then pour in the mould, cool off into the alloy ingot at last, current zinc-aluminum-magnesium-boron alloy ingot generally pours the cooling rate who comes the acceleration alloy to smelt on the mould through water in actual production, and efficiency is comparatively low, for this reason, the utility model provides a current not enough is solved to zinc-aluminum-magnesium-boron alloy ingot large-scale production high-efficient cooling system.

Disclosure of Invention

The utility model aims to provide a: in order to solve the problems in the background, the utility model provides a zinc-aluminum-magnesium-boron alloy ingot large-scale production high-efficiency cooling system.

The utility model discloses a realize above-mentioned purpose and specifically adopt following technical scheme:

the utility model provides a high-efficient cooling system of zinc-aluminum-magnesium-boron alloy ingot large-scale production, includes the driving plate and is used for supporting the supporting leg of driving plate, horizontal slidable mounting in driving plate top has the board of placing, place the standing groove that the board top evenly offered and is used for placing the mould, the driving plate bottom is installed and is used for radiating water-cooling component, install the support body that is located its top on the driving plate, the support body bottom rotates through the pivot and installs radiator fan, the support body top is installed and is acted on radiator fan's interlock subassembly works as when water-cooling component starts, through the interlock subassembly so that radiator fan rotates.

As preferred technical scheme, install outlet pipe and inlet tube on the water-cooling module, the interlock subassembly is including installing the water pump in the water-cooling module outside, the outlet pipe with the water pump water inlet is connected, the top is installed and is acted on the support body radiator fan's driving piece, the delivery port of water pump with be connected with communicating pipe between the driving piece, the inside cavity and the outside intercommunication of support body have the drain pipe, and it is used for discharging the inside water of driving piece, passes through the water pump when the inside water of outlet pipe passes through during the driving piece, through the driving piece so that radiator fan rotates.

As the preferred technical scheme, the driving piece intercommunication is in the mounting disc at support body top, the vertical rotation of mounting disc installs drive water wheels, install on the mounting disc and be used for assaulting the spray tube of drive water wheels flabellum, the spray tube with communicating pipe is connected, drive water wheels with install the driving medium between the radiator fan, work as when drive water wheels rotates, through the driving medium so that radiator fan rotates.

As a preferred technical scheme, a rotating rod is horizontally and rotatably arranged in the mounting disc, and the driving water wheel is arranged on the rotating rod; the transmission part comprises two bevel gears which are meshed with each other, one end of the rotating rod is located outside the mounting disc and connected with one bevel gear, and a rotating shaft of the cooling fan is connected with the other bevel gear.

As preferred technical scheme, water cooling unit is including installing the box of driving plate bottom, the box top be the opening and with the driving plate is linked together, the outlet pipe intercommunication is in on the box, still including installing a plurality of on the supporting leg and be located the connecting block of bottom half, inside cavity and the inlet tube intercommunication of being of connecting block are in on the connecting block, a plurality of cooling tubes are installed to the even vertical intercommunication in connecting block top, the cooling tube passes the box is located inside.

As the preferred technical scheme, two baffles are symmetrically and fixedly arranged at the top of the transmission plate, a plurality of pulleys are rotatably arranged on the two opposite sides of the placing plate in a horizontal array mode, and sliding grooves for the pulleys to slide are formed in the two opposite sides of the baffles along the length of the baffles.

According to the preferable technical scheme, the two opposite sides of the placing groove are provided with limiting grooves along the length direction of the placing groove, and the die is fixedly provided with a limiting block which is inserted into the limiting grooves.

The utility model has the advantages as follows:

the utility model discloses when water-cooling component starts, make radiator fan rotate through the interlock subassembly to realize melting the cooling of water to the alloy through water-cooling and forced air cooling, thereby further improved cooling rate, consequently more have the practicality.

Drawings

Fig. 1 is a schematic perspective view of the present invention;

fig. 2 is a schematic view of another three-dimensional structure of the present invention;

FIG. 3 is an exploded view of a portion of the structure of the present invention;

FIG. 4 is a schematic view of a part of the structure of the present invention;

FIG. 5 is another schematic structural view of the present invention;

FIG. 6 is a front view of the present invention;

fig. 7 is a sectional view taken along line a-a of fig. 6 according to the present invention;

fig. 8 is a sectional view taken along line B-B of fig. 6 in accordance with the present invention;

reference numerals: 1. a drive plate; 2. supporting legs; 3. placing the plate; 4. a placement groove; 5. a water-cooling assembly; 501. a box body; 502. connecting blocks; 503. a cooling tube; 6. a frame body; 7. a linkage assembly; 701. a water pump; 702. a communicating pipe; 703. a water discharge pipe; 8. a transmission member; 801. a bevel gear; 9. a heat radiation fan; 10. a water outlet pipe; 11. a water inlet pipe; 12. a drive member; 1201. mounting a disc; 1202. driving a water wheel; 1203. a nozzle; 13. rotating the rod; 14. a pulley; 15. a chute; 16. a limiting groove; 17. a limiting block; 18. and a baffle plate.

Detailed Description

The present invention will be further described with reference to the accompanying drawings.

The same or similar reference numbers in the drawings of the embodiments of the present invention correspond to the same or similar components; in the description of the present invention, it should be understood that if the terms "head", "tail", "top", "bottom", "left", "right", "front", "back", "inner", "outer", etc. indicate an orientation or a positional relationship based on the orientation or the positional relationship shown in the drawings, it is only for convenience of description of the present invention, but does not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and therefore, the terms describing the positional relationship in the drawings are only used for illustrative purposes and are not to be construed as limitations of the present patent, and those skilled in the art can understand the specific meanings of the terms according to specific situations.

In order to make the purpose, technical solution and advantages of the embodiments of the present invention clearer, the attached drawings in the embodiments of the present invention will be combined below to clearly and completely describe the technical solution in the embodiments of the present invention.

As shown in fig. 1-8, a zinc-aluminum-magnesium-boron alloy ingot large-scale production efficient cooling system comprises a transmission plate 1 and supporting legs 2 for supporting the transmission plate 1, wherein a placing plate 3 is horizontally installed at the top of the transmission plate 1 in a sliding manner, placing grooves 4 for placing molds are evenly formed in the top of the placing plate 3, a water cooling assembly 5 for heat dissipation is installed at the bottom of the transmission plate 1, a frame body 6 located above the transmission plate 1 is installed on the transmission plate 1, a heat dissipation fan 9 is installed at the bottom of the frame body 6 in a rotating manner through a rotating shaft, a linkage assembly 7 acting on the heat dissipation fan 9 is installed at the top of the frame body 6, when the water cooling assembly 5 is started, the heat dissipation fan 9 is rotated through the linkage assembly 7, it should be noted that conveying belts can be installed at two ends of the transmission plate 1, the conveying belts convey the placing plate 3 onto the transmission plate 1, and a plurality of molds are placed on the placing plate 3, the mould is internally poured to have the alloy melt water, start water-cooling subassembly 5 this moment and cool down the mould through water-cooling subassembly 5, it needs to explain that, water-cooling subassembly 5 is current structure, make water spray to the mould bottom through water-cooling subassembly 5, thereby realize the cooling, when water-cooling subassembly 5 starts, make radiator fan 9 rotate through interlock subassembly 7, thereby realize the cooling to the alloy melt water through water-cooling and forced air cooling, thereby further improved cooling rate, consequently, more has the practicality.

As shown in fig. 1, 2 and 7, in some embodiments, a water outlet pipe 10 and a water inlet pipe 11 are installed on the water cooling module 5, the water outlet pipe 10 and the water inlet pipe 11 are components of the existing water cooling module 5, an external water pipe is connected with the water inlet pipe 11 so that the water cooling module 5 cools the molten alloy water and then flows out of the water outlet pipe 10, the linkage module 7 includes a water pump 701 installed outside the water cooling module 5, the water outlet pipe 10 is connected with a water inlet of the water pump 701, a driving member 12 acting on the heat dissipation fan 9 is installed at the top of the frame body 6, a communication pipe 702 is connected between a water outlet of the water pump 701 and the driving member 12, a water discharge pipe 703 is hollow inside the frame body 6 and communicated with the outside and used for discharging water inside the driving member 12, when the water inside the water outlet pipe 10 passes through the driving member 12 through the water pump 701, the heat dissipation fan 9 is rotated by the driving member 12, when the water outlet pipe 10 discharges, water is pumped into the driving part 12 through the water pump 701, water is discharged into the frame body 6 through the driving part 12 and finally discharged from the water discharge pipe 703, the water discharge pipe 703 can be externally connected with a pipeline to prevent water from flowing into the ground, and the driving part 12 is driven by the power of the water to move, so that the rotation of the heat radiation fan 9 is realized.

As shown in fig. 1, 2, 4 and 7, in some embodiments, the driving member 12 is connected to a mounting plate 1201 on the top of the frame body 6, the mounting plate 1201 vertically and rotatably mounts a driving water wheel 1202, a nozzle 1203 for impacting a fan blade of the driving water wheel 1202 is mounted on the mounting plate 1201, the nozzle 1203 is connected to the communication pipe 702, a transmission member 8 is mounted between the driving water wheel 1202 and the cooling fan 9, when the driving water wheel 1202 rotates, the cooling fan 9 rotates through the transmission member 8, water enters the communication pipe 702 through the water pump 701, and then the water is sprayed out from the nozzle 1203, so as to impact the driving water wheel 1202 to rotate, so that the cooling fan 9 rotates, and the cooling fan 9 rotates through the transmission member 8.

As shown in fig. 1, 2, 7 and 8, in some embodiments, a rotating rod 13 is horizontally and rotatably mounted inside the mounting plate 1201, and the driving water wheel 1202 is mounted on the rotating rod 13; the transmission member 8 includes two intermeshing's bevel gear 801, and the one end of dwang 13 is located the mounting disc 1201 outside and is connected with one of them bevel gear 801, and radiator fan 9's pivot is connected with another bevel gear 801, and that is to say, when drive water wheels 1202 rotates, can drive dwang 13 and rotate, thereby dwang 13 rotates and drives the bevel gear 801 of installing on dwang 13 and rotate, thereby make the bevel gear 801 of installing on radiator fan 9 rotate, realized radiator fan 9's rotation.

As shown in fig. 1, 5, 6 and 7, in some embodiments, the water cooling assembly 5 includes a box 501 installed at the bottom of the transmission plate 1, the top of the box 501 is open and is communicated with the transmission plate 1, a water outlet pipe 10 is communicated with the box 501, and further includes a connection block 502 installed on the plurality of support legs 2 and located at the bottom of the box 501, the connection block 502 is hollow and has a water inlet pipe 11 communicated with the connection block 502, the top of the connection block 502 is uniformly and vertically communicated with a plurality of cooling pipes 503, the cooling pipes 503 pass through the box 501 and are located inside, when the water inlet pipe 11 is drained, water enters the inside of the connection block 502, so that the plurality of cooling pipes 503 are drained, water sprayed from the cooling pipes 503 passes through the transmission plate 1 and is sprayed at the bottom of the mold, so as to cool the molten alloy water, and then the water sprayed from the cooling pipes 503 flows into the bottom of the box 501 due to the effect of gravity, so that the water inside the tank 501 is pumped out by the water pump 701 to provide power for driving the water wheel 1202.

As shown in fig. 1 and 3, in some embodiments, two baffles 18 are symmetrically and fixedly arranged at the top of the transmission plate 1, a plurality of pulleys 14 are rotatably arranged in an array manner on two opposite sides of the placing plate 3, sliding grooves 15 for the pulleys 14 to slide are formed in two opposite sides of the baffles 18 along the length of the baffles, and the pulleys 14 and the sliding grooves 15 are designed to play a role in guiding and limiting, so that the placing plate 3 is more smooth when moving.

As shown in fig. 1 and 3, in some embodiments, the two opposite sides of the placement groove 4 are both provided with a limiting groove 16 along the length direction thereof, the mold is fixedly provided with a limiting block 17 for being inserted into the limiting groove 16, and the design of the limiting groove 16 and the limiting block 17 makes the mold not easy to displace when placed in the limiting groove 16, thereby playing a role in limiting.

The foregoing examples are given for the purpose of illustrating the present invention in a clear and non-restrictive manner, and it will be apparent to those skilled in the art that variations and modifications of the present invention may be made in other variations and modifications based on the foregoing description, and it is not necessary or necessary to exhaustively enumerate all embodiments, and all such variations and modifications as are obvious and desirable in the art are within the scope of the present invention.

Claims (7)

1. A zinc-aluminum-magnesium-boron alloy ingot large-scale production efficient cooling system is characterized by comprising a transmission plate (1) and supporting legs (2) for supporting the transmission plate (1), a placing plate (3) is horizontally and slidably arranged at the top of the transmission plate (1), placing grooves (4) for placing molds are uniformly formed in the top of the placing plate (3), a water cooling component (5) for heat dissipation is arranged at the bottom of the transmission plate (1), a frame body (6) positioned above the transmission plate (1) is arranged on the transmission plate (1), a cooling fan (9) is rotatably arranged at the bottom of the frame body (6) through a rotating shaft, the top of the frame body (6) is provided with a linkage component (7) acting on the heat radiation fan (9), when the water cooling assembly (5) is started, the heat radiation fan (9) is rotated through the linkage assembly (7).

2. The high-efficiency cooling system for large-scale production of zinc-aluminum-magnesium-boron alloy ingots according to claim 1, it is characterized in that the water cooling component (5) is provided with a water outlet pipe (10) and a water inlet pipe (11), the linkage component (7) comprises a water pump (701) arranged on the outer side of the water cooling component (5), the water outlet pipe (10) is connected with a water inlet of the water pump (701), a driving piece (12) acting on the heat dissipation fan (9) is arranged at the top of the frame body (6), a communicating pipe (702) is connected between the water outlet of the water pump (701) and the driving piece (12), the inside of the frame body (6) is hollow, the outer side of the frame body is communicated with a water discharge pipe (703), the water-cooling device is used for discharging water in the driving part (12), and when the water in the water outlet pipe (10) passes through the driving part (12) through the water pump (701), the heat-cooling fan (9) is rotated through the driving part (12).

3. The system for cooling the zinc-aluminum-magnesium-boron alloy ingot in large scale production with high efficiency according to claim 2, wherein the driving piece (12) is communicated with a mounting disc (1201) on the top of the frame body (6), the mounting disc (1201) is vertically and rotatably provided with a driving water wheel (1202), a spray pipe (1203) for impacting fan blades of the driving water wheel (1202) is mounted on the mounting disc (1201), the spray pipe (1203) is connected with the communicating pipe (702), a transmission piece (8) is mounted between the driving water wheel (1202) and the cooling fan (9), and when the driving water wheel (1202) rotates, the cooling fan (9) rotates through the transmission piece (8).

4. The system for cooling the zinc-aluminum-magnesium-boron alloy ingot in large scale production with high efficiency according to claim 3, characterized in that a rotating rod (13) is horizontally and rotatably installed inside the installation disc (1201), and the driving water wheel (1202) is installed on the rotating rod (13); the transmission piece (8) comprises two bevel gears (801) which are meshed with each other, one end of the rotating rod (13) is located outside the mounting disc (1201) and connected with one bevel gear (801), and a rotating shaft of the cooling fan (9) is connected with the other bevel gear (801).

5. The system for efficiently cooling the zinc-aluminum-magnesium-boron alloy ingot in large-scale production according to claim 4, wherein the water cooling assembly (5) comprises a box body (501) installed at the bottom of the transmission plate (1), the top of the box body (501) is open and communicated with the transmission plate (1), the water outlet pipe (10) is communicated with the box body (501), the system further comprises a connecting block (502) installed on the plurality of support legs (2) and located at the bottom of the box body (501), the connecting block (502) is hollow, the water inlet pipe (11) is communicated with the connecting block (502), the top of the connecting block (502) is uniformly and vertically communicated with the plurality of cooling pipes (503), and the cooling pipes (503) penetrate through the box body (501) and are located inside.

6. The system for efficiently cooling the zinc-aluminum-magnesium-boron alloy ingot in large-scale production according to claim 1, wherein two baffles (18) are symmetrically and fixedly arranged at the top of the transmission plate (1), a plurality of pulleys (14) are horizontally and rotatably arranged on two opposite sides of the placing plate (3) in an array manner, and chutes (15) for the pulleys (14) to slide are formed in two opposite sides of each baffle (18) along the length of the baffle.

7. The system for cooling the zinc-aluminum-magnesium-boron alloy ingot in large scale production in accordance with claim 1, wherein the two opposite sides of the placement groove (4) are provided with limiting grooves (16) along the length direction thereof, and the mold is fixedly provided with limiting blocks (17) inserted into the limiting grooves (16).

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