CN219283710U - Quick cooling device - Google Patents

Abstract

The utility model discloses a rapid cooling device which comprises a platform, a U-shaped cooling box, a water cooling mechanism and an air cooling mechanism, wherein the U-shaped cooling box is fixedly arranged at the top of the platform, two U-shaped frames are fixedly arranged at the top of the platform, the two U-shaped frames are symmetrically arranged at two sides of the U-shaped cooling box, conveying rollers are rotatably arranged on the two U-shaped frames, the same mesh belt conveying belt is wound on the two conveying rollers, the mesh belt conveying belt penetrates through the U-shaped cooling box, the water cooling mechanism and the air cooling mechanism are both arranged on the U-shaped cooling box, the water cooling mechanism is used for cooling toughened glass in a water cooling mode, and the air cooling mechanism is used for cooling toughened glass in an air cooling mode. The utility model has reasonable design and good practicability, can simultaneously cool the upper surface and the lower surface of the toughened glass by water cooling and air cooling, and improves the cooling quality and the cooling efficiency of the toughened glass.

Description

Quick cooling device

Technical Field

The utility model relates to the technical field of cooling equipment, in particular to a rapid cooling device.

Background

The toughened glass belongs to safety glass, is prestressed glass, has the advantages of good safety, high strength, thermal stability and the like, and is widely applied in real life. When the toughened glass is produced and processed, the toughened glass is required to be cooled by the cooling device because the toughened glass has higher temperature after being processed, and the heat on the surface of the toughened glass is dissipated. The existing cooling device generally adopts a water cooling mode to cool the toughened glass, and adopts water recycling after cooling during water cooling and cooling, so that the cooling device has the purpose of saving cooling water resources.

When the prior cooling mode is adopted for cooling the toughened glass, a conveyor belt is mostly adopted for conveying the toughened glass with heat at a constant speed, and then sprayed on the surface of the toughened glass by using sprayed cooling water for cooling, so that the prior cooling mode can meet the basic cooling effect, but the following defects still exist in actual operation: during cooling of toughened glass, cooling water can only be sprayed on one surface of the toughened glass to cool the toughened glass, and the other surface of the toughened glass is not easy to contact with the cooling water, so that heat of the lower surface of the toughened glass can be slowly dissipated, the cooling efficiency of the toughened glass is low, and the toughened glass is not uniform enough, and therefore, the quick cooling device is used for solving the problems.

Disclosure of Invention

(one) solving the technical problems

Aiming at the defects of the prior art, the utility model provides a rapid cooling device, which solves the problems that only one surface of toughened glass can be sprayed with cooling water to cool, the other surface of the toughened glass is not easy to contact with the cooling water, the cooling efficiency of the whole toughened glass is low, and the cooling is not uniform.

(II) technical scheme

In order to achieve the above purpose, the present utility model provides the following technical solutions: the rapid cooling device comprises a platform, a U-shaped cooling box, a water cooling mechanism and an air cooling mechanism, wherein the U-shaped cooling box is fixedly arranged at the top of the platform, two U-shaped frames are fixedly arranged at the top of the platform, the two U-shaped frames are symmetrically arranged at two sides of the U-shaped cooling box, a conveying roller is rotatably arranged on each of the two U-shaped frames, the two conveying rollers are wound with the same mesh belt conveying belt, the mesh belt conveying belt penetrates through the U-shaped cooling box, the water cooling mechanism and the air cooling mechanism are both arranged on the U-shaped cooling box, the water cooling mechanism is used for cooling toughened glass in a water cooling mode, and the air cooling mechanism is used for cooling toughened glass in an air cooling mode.

Preferably, the water cooling mechanism comprises two support plates, two hollow vertical shafts, two sprinkling disks, two cooling water inlet pipes, two driven bevel gears, two driving shafts, two driving bevel gears, two sprockets, chains and a motor, wherein the two support plates are fixedly arranged on the inner wall of the rear side of the U-shaped cooling box, the two hollow vertical shafts are respectively and rotatably arranged on the corresponding support plates, one ends of the two hollow vertical shafts, which are close to each other, respectively penetrate through the corresponding support plates, the two sprinkling disks are respectively and fixedly arranged at one ends of the two hollow vertical shafts, the two sprinkling disks are mutually close to each other, a plurality of sprinkling holes are formed at equal intervals on one side of the two sprinkling disks, a mesh belt conveyer belt penetrates through between the two sprinkling disks, the two cooling water inlet pipes are fixedly arranged in the U-shaped cooling box, the rear ends of the two cooling water inlet pipes are respectively extended to the corresponding hollow shafts, the rear ends of the two cooling water inlet pipes are respectively extended out of the U-shaped cooling box, the two driven bevel gears are respectively and fixedly sleeved on the corresponding vertical shafts, the two driving shafts are respectively and fixedly arranged at the two driving shafts, the two driving shafts are respectively and fixedly arranged at the rear ends of the two driving bevel gears are respectively and fixedly meshed with the two driving bevel gears, the driving shafts are respectively and fixedly arranged at the two driving shafts are respectively and fixedly arranged at the rear ends of the driving shafts and the two driving shafts are respectively and fixedly arranged at the corresponding driving shafts.

Preferably, sealing rings are fixedly arranged on the inner walls of the two hollow vertical shafts, and the two cooling water inlet pipes are respectively in rotary sealing fit with the corresponding hollow vertical shafts through the corresponding sealing rings.

Preferably, the air cooling mechanism comprises an upper cold air conveying pipe, a plurality of upper air outlet spray heads, a plurality of lower cold air conveying pipes and a plurality of lower air outlet spray heads, wherein the upper cold air conveying pipe and the lower cold air conveying pipes are fixedly arranged in the U-shaped cooling box, the plurality of upper air outlet spray heads are fixedly arranged at the bottom of the upper cold air conveying pipe and are distributed at equal intervals, and the plurality of lower air outlet spray heads are fixedly arranged at the top of the lower cold air conveying pipe and are distributed at equal intervals.

Preferably, the top of platform has seted up the water receiving tank that is located U type cooling tank, and the bottom fixed mounting of platform has the drain pipe, and the drain pipe is linked together with the water receiving tank.

Preferably, the bottom inner wall of the water receiving tank is of an inclined surface structure.

(III) beneficial effects

The utility model provides a rapid cooling device. The beneficial effects are as follows:

(1) This quick cooling device through utilizing the guipure conveyer belt, can convey toughened glass case U type cooling incasement, through utilizing by two backup pads, two hollow vertical axes, two watering dish, two cooling water advance pipe, two driven bevel gears, two drive shafts, two initiative bevel gears, two sprocket, chain and motor combination constitution's water-cooling mechanism, can carry out even effectual water-cooling simultaneously to toughened glass's upper and lower two surfaces.

(2) This quick cooling device through utilizing the forced air cooling mechanism that comprises last air conditioning conveyer pipe, a plurality of last shower nozzle of giving vent to anger, lower air conditioning conveyer pipe and a plurality of shower nozzle combination of giving vent to anger down, can carry out even effectual forced air cooling to toughened glass's upper and lower two surfaces simultaneously.

(3) This quick cooling device carries out under the combined action of water-cooling and forced air cooling simultaneously through two upper and lower surfaces to toughened glass, can improve the cooling quality and the cooling efficiency to toughened glass, has solved current cooling device for toughened glass production and can only carry out single face cooling to toughened glass and cool down, and cooling efficiency is low, the not good problem of cooling quality.

Drawings

FIG. 1 is a schematic perspective view of the present utility model;

FIG. 2 is a schematic cross-sectional view of the front view of the present utility model;

FIG. 3 is an enlarged schematic view of portion A of FIG. 2;

fig. 4 is a schematic cross-sectional side view of the present utility model.

In the figure: 1. a platform; 2. a U-shaped cooling box; 3. a U-shaped frame; 4. a conveying roller; 5. a mesh belt conveyor belt; 6. a support plate; 7. a hollow vertical shaft; 8. a watering plate; 9. a cooling water inlet pipe; 10. a driven bevel gear; 11. a drive shaft; 12. a driving bevel gear; 13. a sprocket; 14. a chain; 15. a motor; 16. a water spraying hole; 17. a cold air delivery pipe; 18. an upper air outlet nozzle; 19. a lower cold air delivery pipe; 20. a lower air outlet nozzle; 21. a water receiving tank; 22. and (5) a water drain pipe.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

In the description of the present utility model, it should be understood that the terms "length", "width", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc. indicate orientations or positional relationships based on the drawings, are merely for convenience in describing the present utility model and simplifying the description, and do not indicate or imply that the apparatus or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model, and furthermore, in the description of the present utility model, the meaning of "a plurality" means two or more unless specifically defined otherwise.

As shown in fig. 1-4, the present utility model provides a technical solution: the utility model provides a quick cooling device, includes platform 1, U type cooling box 2, water-cooling mechanism and forced air cooling mechanism, wherein:

the U-shaped cooling box 2 is fixedly mounted at the top of the platform 1, two U-shaped frames 3 are fixedly mounted at the top of the platform 1, the two U-shaped frames 3 are symmetrically arranged on two sides of the U-shaped cooling box 2, the two U-shaped frames 3 are respectively provided with a conveying roller 4 in a rotating mode, the two conveying rollers 4 are respectively provided with the same mesh belt conveying belt 5 in a winding mode, the mesh belt conveying belt 5 is used for conveying toughened glass, the mesh belt conveying belt 5 is made of stainless steel materials, a driving motor is mounted on one U-shaped frame 3 of the two U-shaped frames 3, the output shaft end of the driving motor is fixedly connected with one end of the conveying rollers 4, the mesh belt conveying belt 5 can be controlled to rotate by the driving motor, the driving principle of the mesh belt conveying belt 5 belongs to the conventional technical means in the prior art, redundant description is omitted, the mesh belt conveying belt 5 penetrates through the U-shaped cooling box 2, the water cooling mechanism and the air cooling mechanism is arranged on the U-shaped cooling box 2, the water cooling mechanism is used for cooling toughened glass, the air cooling mechanism is used for cooling the toughened glass, the cooling mechanism is required to be cooled, the cooling mechanism is located on the left side, and the cooling mechanism is located on the cooling side of the air cooling mechanism can be cooled, and the cooling effect can be achieved.

The water cooling mechanism comprises two support plates 6, two hollow vertical shafts 7, two sprinkling disks 8, two cooling water inlet pipes 9, two driven bevel gears 10, two driving shafts 11, two driving bevel gears 12, two chain wheels 13, chains 14 and motors 15, wherein the two support plates 6 are fixedly arranged on the inner wall of the rear side of the U-shaped cooling box 2, the two hollow vertical shafts 7 are respectively and rotatably arranged on the corresponding support plates 6, one ends of the two hollow vertical shafts 7, which are close to each other, respectively penetrate through the corresponding support plates 6, the two sprinkling disks 8 are respectively and fixedly arranged at one ends of the two hollow vertical shafts 7, a plurality of sprinkling holes 16 are formed in the equal interval at one sides of the two sprinkling disks 8, which are close to each other, the mesh belt conveyer belt 5 penetrates through the space between the two sprinkling disks 8, the two cooling water inlet pipes 9 are fixedly arranged in the U-shaped cooling box 2, the front ends of the two cooling water inlet pipes 9 respectively extend to the corresponding hollow vertical shafts 7, the rear ends of the two cooling water inlet pipes 9 respectively extend to the outside of the U-shaped cooling box 2, the two cooling water inlet pipes 9 are used for conveying cooling water, the two water spraying disks 8 are arranged to spray water to the upper surface and the lower surface of toughened glass respectively and cool down the toughened glass simultaneously, the cooling effect on the toughened glass is improved, the rear ends of the two cooling water inlet pipes 9 are fixedly connected with the discharge ends of the cooling water booster pumps, the cooling water can be conveyed to the two water spraying disks 8 by the cooling water booster pumps, the two driven bevel gears 10 are respectively and fixedly sleeved on the corresponding hollow vertical shafts 7, the two driving shafts 11 are respectively and rotatably arranged in the U-shaped cooling box 2, the two driving bevel gears 12 are respectively and fixedly arranged at the front ends of the corresponding driving shafts 11, the two driving bevel gears 12 are respectively meshed with the corresponding driven bevel gears 10, the rear ends of the two driving shafts 11 extend to the outside of the U-shaped cooling box 2, the two chain wheels 13 are fixedly sleeved at the rear ends of the corresponding driving shafts 11 respectively, the chain 14 is wound on the two chain wheels 13, the motor 15 is fixedly installed at the rear side of the U-shaped cooling box 2, the output shaft end of the motor 15 is fixedly connected with the rear end of one driving shaft 11 of the two driving shafts 11, the two driving shafts 11 can be controlled to rotate simultaneously by utilizing the transmission effect of the two chain wheels 13 and the chain 14, the two driving bevel gears 12 are respectively in meshed transmission effect with the corresponding driven bevel gears 10, and the two hollow vertical shafts 7 can be controlled to drive the corresponding sprinkling disks 8 to rotate simultaneously, so that cooling water can be uniformly sprinkled on the upper surface and the lower surface of toughened glass.

The air cooling mechanism includes an upper air delivery pipe 17, a plurality of upper air delivery nozzles 18, a lower air delivery pipe 19 and a plurality of lower air delivery nozzles 20, wherein the upper air delivery pipe 17 and the lower air delivery pipe 19 are fixedly installed in the U-shaped cooling box 2, the plurality of upper air delivery nozzles 18 are fixedly installed at the bottom of the upper air delivery pipe 17 and are distributed at equal intervals, the plurality of lower air delivery nozzles 20 are fixedly installed at the top of the lower air delivery pipe 19 and are distributed at equal intervals, the upper air delivery pipe 17 and the lower air delivery pipe 19 are utilized to deliver air, the upper surface of toughened glass can be uniformly sprayed with the air by utilizing the plurality of upper air delivery nozzles 18 to cool the upper surface of toughened glass, and the lower surface of toughened glass can be uniformly sprayed with the air by utilizing the plurality of lower air delivery nozzles 20 to cool the air, and the rear end of the upper air delivery pipe 17 and the rear end of the lower air delivery pipe 19 are fixedly connected with the discharge end of the air cooler.

Through the structure, the rapid cooling device provided by the utility model can simultaneously perform water cooling and air cooling on the upper surface and the lower surface of the toughened glass, so that the cooling quality and the cooling efficiency of the toughened glass are improved, when the rapid cooling device is particularly operated, the toughened glass is placed on the mesh belt conveying belt 5, the mesh belt conveying belt 5 can be used for conveying the toughened glass horizontally to the right, during the process that the toughened glass passes through the U-shaped cooling box 2, the two cooling water inlet pipes 9 are used for conveying the cooling water into the two sprinkling disks 8, the cooling water sprayed by the upper sprinkling disks 8 can perform water cooling on the upper surface of the toughened glass, the cooling water sprayed by the lower sprinkling disks 8 can perform water cooling on the lower surface of the toughened glass, the toughened glass is operated by the starting motor 15, the transmission of the two chain wheels 13 and the chains 14 is utilized, and cooperate two initiative bevel gears 12 respectively with the meshing transmission of corresponding driven bevel gears 10, can control two hollow vertical shafts 7 drive corresponding watering dish 8 and rotate simultaneously, and then can evenly spray cooling water on toughened glass's upper and lower two surfaces, improve quality and efficiency to toughened glass water-cooling, when the toughened glass after the water-cooling passes between last air-conditioning conveyer pipe 17 and lower air-conditioning conveyer pipe 19, control the air-conditioning and carry out the transportation in last air-conditioning conveyer pipe 17 and lower air-conditioning conveyer pipe 19, make from a plurality of last shower nozzle 18 spun air-conditioning can carry out the forced air cooling to toughened glass's upper surface, from a plurality of shower nozzle 20 spun air-conditioning can carry out the forced air cooling to toughened glass's lower surface, and then realized carrying out the effect that the water-cooling cooled down is cooled down to toughened glass's upper and lower two surfaces simultaneously.

In this embodiment, sealing rings are fixedly installed on the inner walls of the two hollow vertical shafts 7, two cooling water inlet pipes 9 are respectively in rotary sealing fit with the corresponding hollow vertical shafts 7 through corresponding sealing rings, and gaps between the cooling water inlet pipes 9 and the hollow vertical shafts 7 can be sealed by utilizing the sealing rings, and it is noted that the sealing rings arranged between the cooling water inlet pipes 9 and the hollow vertical shafts 7 are rotary dynamic seals, for example, the sealing rings are composed of a slip ring made of filled polytetrafluoroethylene and a rubber O-shaped ring for providing elasticity.

In this embodiment, the water receiving tank 21 located in the U-shaped cooling tank 2 is provided at the top of the platform 1, the drain pipe 22 is fixedly installed at the bottom of the platform 1, the drain pipe 22 is communicated with the water receiving tank 21, the water receiving tank 21 is used for receiving cooling water after use, the drain pipe 22 is used for discharging cooling water after use, it should be noted that the drain pipe 22 can be connected with the cooling water collecting tank for recovering cooling water after use, so that subsequent recycling is facilitated, the bottom inner wall of the water receiving tank 21 is of an inclined plane structure, and cooling water entering the water receiving tank 21 can be completely discharged through the drain pipe 22 by setting the bottom inner wall of the water receiving tank 21 as an inclined plane.

In this embodiment, it should be noted that, a control switch is installed on the U-shaped cooling box 2, the motor 15 and the control switch are connected with an external power line through a wire, and the control switch can control the start and stop of the motor 15.

The above description is merely an embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art can easily think about changes or substitutions within the technical scope of the present utility model, and it is intended to cover the scope of the present utility model. Therefore, the protection scope of the present utility model shall be subject to the protection scope of the claims.

Claims (6)

1. A rapid cooling device, characterized in that: including platform (1), U type cooling box (2), water-cooling mechanism and forced air cooling mechanism, U type cooling box (2) fixed mounting is in the top of platform (1), the top fixed mounting of platform (1) has two U type frame (3), two U type frame (3) symmetry sets up the both sides of U type cooling box (2), two all rotate on U type frame (3) and install transfer roller (4), two around being equipped with same guipure conveyer belt (5) on transfer roller (4), guipure conveyer belt (5) run through U type cooling box (2), water-cooling mechanism with forced air cooling mechanism all sets up on U type cooling box (2), water-cooling mechanism is used for cooling down toughened glass water, forced air cooling mechanism is used for cooling down toughened glass forced air cooling.

2. A rapid cooling device according to claim 1, characterized in that: the water cooling mechanism comprises two support plates (6), two hollow vertical shafts (7), two sprinkling disks (8), two cooling water inlet pipes (9), two driven bevel gears (10), two driving shafts (11), two driving bevel gears (12), two chain wheels (13), a chain (14) and a motor (15), wherein the two support plates (6) are fixedly installed on the inner wall of the rear side of the U-shaped cooling box (2), the two hollow vertical shafts (7) are respectively rotatably installed on the corresponding support plates (6), one ends of the two hollow vertical shafts (7) close to each other respectively penetrate through the corresponding support plates (6), the two sprinkling disks (8) are respectively fixedly installed at one ends of the two hollow vertical shafts (7) close to each other, a plurality of water holes (16) are formed in the interval between one sides of the two sprinkling disks (8) close to each other, the mesh belt conveying belt (5) penetrates through the space between the two sprinkling disks (8), the two cooling water inlet pipes (9) are respectively installed at the two hollow vertical shafts (9) and extend to the cooling water inlet pipes (9) at the inner ends of the two hollow vertical shafts (9) respectively, the two driven bevel gears (10) are fixedly sleeved on the corresponding hollow vertical shafts (7), the two driving shafts (11) are rotatably installed in the U-shaped cooling boxes (2), the two driving bevel gears (12) are fixedly installed at the front ends of the corresponding driving shafts (11), the two driving bevel gears (12) are meshed with the corresponding driven bevel gears (10), the rear ends of the two driving shafts (11) are extended out of the U-shaped cooling boxes (2), the two chain wheels (13) are fixedly sleeved on the rear ends of the corresponding driving shafts (11), the chain (14) are wound on the two chain wheels (13), the motor (15) is fixedly installed at the rear side of the U-shaped cooling boxes (2), and the output shaft ends of the motor (15) are fixedly connected with the rear end of one driving shaft (11) of the two driving shafts (11).

3. A rapid cooling device according to claim 2, characterized in that: sealing rings are fixedly arranged on the inner walls of the two hollow vertical shafts (7), and the two cooling water inlet pipes (9) are respectively in rotary sealing fit with the corresponding hollow vertical shafts (7) through the corresponding sealing rings.

4. A rapid cooling device according to claim 1, characterized in that: the air cooling mechanism comprises an upper cold air conveying pipe (17), a plurality of upper air outlet spray nozzles (18), a lower cold air conveying pipe (19) and a plurality of lower air outlet spray nozzles (20), wherein the upper cold air conveying pipe (17) and the lower cold air conveying pipe (19) are fixedly installed in the U-shaped cooling box (2), the upper air outlet spray nozzles (18) are fixedly installed at the bottom of the upper cold air conveying pipe (17) and are distributed at equal intervals, and the lower air outlet spray nozzles (20) are fixedly installed at the top of the lower cold air conveying pipe (19) and are distributed at equal intervals.

5. A rapid cooling device according to claim 1, characterized in that: the top of platform (1) has seted up and is located water receiving tank (21) in U type cooling tank (2), the bottom fixed mounting of platform (1) has drain pipe (22), drain pipe (22) with water receiving tank (21) are linked together.

6. A rapid cooling device according to claim 5, wherein: the bottom inner wall of the water receiving tank (21) is of an inclined surface structure.

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