CN218321139U - Cooling device after hot dipping of toughened glass - Google Patents
Cooling device after hot dipping of toughened glass Download PDFInfo
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- CN218321139U CN218321139U CN202221712998.4U CN202221712998U CN218321139U CN 218321139 U CN218321139 U CN 218321139U CN 202221712998 U CN202221712998 U CN 202221712998U CN 218321139 U CN218321139 U CN 218321139U
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Abstract
The utility model discloses a cooling device for tempered glass after hot dipping, which comprises a cooling furnace, an air outlet component, an air collecting shell, a circulating mechanism and a refrigeration module, wherein the air inlet end of the circulating mechanism is correspondingly provided with the air collecting shell, the air outlet end of the circulating mechanism is correspondingly provided with the air outlet component, and the refrigeration module is arranged on an air duct pipeline of the circulating mechanism and cools the circulating air flow; the air outlet assembly and the air collecting shell are arranged in the inner cavity of the cooling furnace in the transverse direction in a positive-opposite mode, a transverse air cooling channel is formed between the air outlet assembly and the air collecting shell, the air outlet assembly is arranged in a reset mode in the direction perpendicular to the air cooling channel, and cooling uniformity and cooling efficiency can be improved.
Description
Technical Field
The utility model belongs to toughened glass homogeneity handles field, in particular to toughened glass's hot dipping after cooling device.
Background
Because the toughened glass has nickel sulfide stones, the toughened glass installed on a building has the self-explosion phenomenon, the toughened glass needs to be subjected to high-temperature heating, heat preservation and cooling in the manufacturing process, and the toughened glass with the self-explosion possibility can be "detonated" in advance to a great extent through homogenization treatment, so that the toughened glass is increasingly valued and adopted by the market. When the cooling stage is performed in the cooling furnace, most of the glass modules are placed in the cooling furnace, gas in the furnace body is circulated through the circulation fan, and heat exchange is performed between the glass modules and the refrigeration module outside the furnace, so that the temperature in the furnace body is reduced.
However, because the interval between glass and the glass is less, single cold wind air outlet can not act on all glass completely, in time under the condition of air current circulation, still make the temperature in the furnace body distribute unevenly, glass's cooling degree is different, not only gets into the cold wind in the furnace body and distributes unevenly, and the hot-blast that forms after cold wind and glass heat exchange lacks because direction and drainage moreover, mostly still gathers in the furnace body and can not in time get into circulation channel, cause the internal holistic cooling of furnace uneven, inefficiency.
Disclosure of Invention
The purpose of the invention is as follows: in order to overcome the defects in the prior art, the utility model provides a tempering glass hot-dipping rear cooling device which can improve the cooling uniformity and the cooling efficiency.
The technical scheme is as follows: in order to achieve the above purpose, the technical scheme of the utility model is as follows:
a cooling device for tempered glass after hot dipping comprises a cooling furnace, an air outlet assembly, an air collecting shell, a circulating mechanism and a refrigerating module, wherein the air inlet end of the circulating mechanism is correspondingly provided with the air collecting shell, the air outlet end of the circulating mechanism is correspondingly provided with the air outlet assembly, and the refrigerating module is arranged on an air duct pipeline of the circulating mechanism and cools circulating air flow; the air outlet assembly and the air collection shell are arranged in the inner cavity of the cooling furnace in a right opposite mode in the transverse direction, a transverse air cooling channel is formed between the air outlet assembly and the air collection shell, and the air outlet assembly is arranged in a reset mode in the direction perpendicular to the air cooling channel.
Further, the air outlet assembly comprises a linear displacement mechanism and an air outlet pipe arranged on the linear displacement mechanism, the linear displacement mechanism is transversely arranged and perpendicular to the air cooling channel, the air outlet pipe is vertically arranged, and a plurality of vertically arranged air outlets are formed in one side, facing the air collection shell, of the air outlet pipe; the air outlet pipe is reset in the width direction of the air cooling channel.
Furthermore, the air collecting shell is of a conical shell structure, and the large end side of the air collecting shell faces the air outlet pipe; the air collection shell collects air flow passing through the glass module.
Furthermore, a guide plate is arranged between the wind collecting end of the wind collecting shell and the inner wall of the cooling furnace.
Furthermore, two groups of supporting structures are arranged at the bottom of the cooling furnace at intervals, a glass module to be cooled is erected on the supporting structures, and a slag collecting groove is formed between the two groups of supporting structures and corresponds to the glass module; and the slag collecting groove collects the broken glass slag.
Further, the supporting structure is an excitation mechanism.
Has the beneficial effects that: the utility model discloses an interval between glass and the glass is just being corresponded to the forced air cooling passageway, the air-cooled air current can be towards carrying out the forced air cooling heat dissipation between each glass through the air-out subassembly under the moving state, avoid the uneven phenomenon of glass surface wind heat dissipation, and the air current after with the glass heat-conduction directly enters into collection wind casing and collects, and outwards derive through circulation mechanism, avoid the long-time diffusion of air current after the heat-conduction and collect in the furnace body, thereby make the forced air cooling air current can the rapid cycle, reach rapid cooling, promote cooling efficiency.
Drawings
FIG. 1 is a perspective view of the overall structure of the present invention;
fig. 2 is another perspective view of the overall structure of the present invention.
Detailed Description
The present invention will be further described with reference to the accompanying drawings.
As shown in fig. 1 and fig. 2, a cooling device for tempered glass after hot dipping comprises a cooling furnace 1, an air outlet assembly 2, an air collecting shell 3, a circulating mechanism 4 and a refrigerating module 5, wherein an air inlet end of the circulating mechanism 4 is correspondingly provided with the air collecting shell 3, the circulating mechanism is an exhaust fan, the refrigerating module is a refrigerator, an air outlet end of the circulating mechanism is correspondingly provided with the air outlet assembly 2, and the refrigerating module 5 is arranged on an air duct pipeline of the circulating mechanism 4 and cools circulating air flow; more than basic supreme, air-out subassembly 2 and collection wind casing 3 are just relative setting in the inner chamber of cooling furnace 1 in the transverse direction, constitute horizontal air-cooled passageway between air-out subassembly 2 and the collection wind casing 3, the interval passageway between air-cooled passageway and the glass is the same, air-out subassembly 2 is toward resetting the setting of moving in the direction of perpendicular to air-cooled passageway, can change the position of air outlet, and the air-cooled air current can be towards carrying out the forced air cooling heat dissipation between each glass, avoids the uneven phenomenon of glass surface wind heat dissipation.
And the air current after with glass heat-conduction directly enters into in the wind-collecting shell and collects to outwards derive through circulation mechanism, avoid the long-time diffusion of air current after the heat-conduction and collect in the furnace body, thereby make the forced air cooling air current can rapid cycle, reach rapid cooling, promote cooling efficiency. And because the air current of the air-out end of the air collection shell is reduced in pressure after being refrigerated by the refrigerator, and the air inlet end of the air collection shell corresponding to the interior of the furnace body is a hot air end, namely a high-pressure side, the pressure difference caused by temperature change is more beneficial to the collection and flow of hot air in the furnace body towards the interior of the air collection shell.
The air outlet assembly 2 comprises a linear displacement mechanism 6 and an air outlet pipe 7 arranged on the linear displacement mechanism, the linear displacement mechanism 6 is an electric screw rod mechanism, the linear displacement mechanism 6 is transversely arranged and perpendicular to the air cooling channel, the air outlet pipe 7 is vertically arranged, and a plurality of vertically arranged air outlets 8 are formed in one side, facing the air collecting shell 3, of the air outlet pipe 7; the air outlet pipe 7 is in reciprocating displacement in the width direction of the air cooling channel, so that the air outlets 8 correspond to gaps among the glass, and the uniform distribution of cold air in the furnace body is ensured.
The air collecting shell 3 is of a conical shell structure, and the large end side of the air collecting shell 3 faces the air outlet pipe 7; the air collecting shell 3 collects air flow passing through the glass module, a guide plate 9 is arranged between the air collecting end of the air collecting shell 3 and the inner wall of the cooling furnace 1, and the air flow passing through heat exchange in the furnace body enters the air collecting shell through the guide plate.
Two groups of supporting structures 12 are arranged at the bottom of the cooling furnace 1 at intervals, a glass module 20 to be cooled is erected on the supporting structures 12, and a slag collecting groove 11 is arranged between the two groups of supporting structures 12 corresponding to the glass module 20; the slag collection groove 11 collects broken glass slag. The supporting structure 12 is an excitation mechanism and is used for enabling the glass assembly 20 and the support of the glass assembly to vibrate vertically in a small amplitude mode, when a plurality of pieces of glass are subjected to self-explosion, the broken glass slag can fall downwards into the slag collecting groove through slight vibration, the broken glass slag is prevented from being clamped between the glass after the self-explosion, and the smoothness of the air cooling channel is guaranteed.
The above description is only a preferred embodiment of the present invention, and it should be noted that: for those skilled in the art, without departing from the principle of the present invention, several improvements and modifications can be made, and these improvements and modifications should also be considered as the protection scope of the present invention.
Claims (6)
1. A cooling device after hot dipping of toughened glass is characterized in that: the cooling device comprises a cooling furnace (1), an air outlet assembly (2), an air collecting shell (3), a circulating mechanism (4) and a refrigerating module (5), wherein the air inlet end of the circulating mechanism (4) is correspondingly provided with the air collecting shell (3), the air outlet end of the circulating mechanism is correspondingly provided with the air outlet assembly (2), and the refrigerating module (5) is arranged on an air duct pipeline of the circulating mechanism (4) and cools circulating air flow; the air-out subassembly (2) and the setting that just is relative of wind collection casing (3) are in the inner chamber of cooling furnace (1) in the transverse direction, constitute horizontal air-cooled passageway between air-out subassembly (2) and the wind collection casing (3), air-out subassembly (2) is towards resetting the setting in the direction of perpendicular to air-cooled passageway.
2. A device for cooling tempered glass after hot dipping according to claim 1, wherein: the air outlet assembly (2) comprises a linear displacement mechanism (6) and an air outlet pipe (7) arranged on the linear displacement mechanism, the linear displacement mechanism (6) is transversely arranged and is perpendicular to the air cooling channel, the air outlet pipe (7) is vertically arranged, and a plurality of vertically arranged air outlets (8) are formed in one side, facing the air collecting shell (3), of the air outlet pipe (7); the air outlet pipe (7) moves towards the reset in the width direction of the air cooling channel.
3. A device for cooling tempered glass after hot dipping according to claim 2, wherein: the air collecting shell (3) is of a conical shell structure, and the large end side of the air collecting shell (3) faces the air outlet pipe (7); the air collecting shell (3) collects air flow passing through the glass module.
4. A device for cooling tempered glass after hot dipping according to claim 3, wherein: a guide plate (9) is arranged between the wind collecting end of the wind collecting shell (3) and the inner wall of the cooling furnace (1).
5. A device for cooling tempered glass after hot dipping according to claim 3, wherein: two groups of supporting structures (12) are arranged at the bottom of the cooling furnace (1) at intervals, a glass module (20) to be cooled is erected on the supporting structures (12), and a slag collecting groove (11) is arranged between the two groups of supporting structures (12) corresponding to the glass module (20); the slag collecting groove (11) collects broken glass slag.
6. A device for cooling tempered glass after hot dipping according to claim 5, wherein: the supporting structure (12) is an excitation mechanism.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CN202221712998.4U CN218321139U (en) | 2022-07-05 | 2022-07-05 | Cooling device after hot dipping of toughened glass |
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CN202221712998.4U CN218321139U (en) | 2022-07-05 | 2022-07-05 | Cooling device after hot dipping of toughened glass |
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CN218321139U true CN218321139U (en) | 2023-01-17 |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN116465154A (en) * | 2023-04-23 | 2023-07-21 | 河北九月厨具股份有限公司 | Hot-dip cooling device and process for toughened glass pot cover |
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2022
- 2022-07-05 CN CN202221712998.4U patent/CN218321139U/en active Active
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN116465154A (en) * | 2023-04-23 | 2023-07-21 | 河北九月厨具股份有限公司 | Hot-dip cooling device and process for toughened glass pot cover |
CN116465154B (en) * | 2023-04-23 | 2024-02-27 | 河北九月厨具股份有限公司 | Hot-dip cooling device and process for toughened glass pot cover |
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