CN210506062U - Air outlet mechanism of curved glass tempering air grid - Google Patents
Air outlet mechanism of curved glass tempering air grid Download PDFInfo
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- CN210506062U CN210506062U CN201921206897.8U CN201921206897U CN210506062U CN 210506062 U CN210506062 U CN 210506062U CN 201921206897 U CN201921206897 U CN 201921206897U CN 210506062 U CN210506062 U CN 210506062U
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Abstract
The utility model relates to a glass tempering technical field, concretely relates to air-out mechanism of curved surface glass tempering air grid. The air outlet mechanism is arranged on a flexible air grid and comprises a fluid smooth structure arranged on the inner wall of the flexible air grid and/or an air outlet airflow directional stable structure arranged on the outer wall of the flexible air grid; the fluid smooth structure is used for reducing resistance when air flows in the flexible air grid circulate, and the air outlet airflow directional stabilizing structure is used for restraining the direction of the sprayed air flow and enabling the flow speed and the flow of the air flow to be more uniform. The air outlet mechanism provided by the technical scheme smoothes the airflow channel with a plurality of folds on the inner wall of the flexible air grid, so that the fluid resistance is reduced; and the additionally arranged independent air nozzle or the fixing piece can not deform, and stably guides the air flow ejected from the air outlet of the flexible air grid, so that the ejection direction, the flow speed and the flow of the air flow are regulated and controlled to be directional, orderly and stable to a certain degree.
Description
Technical Field
The utility model relates to a glass tempering technical field, concretely relates to curved surface glass tempering air grid air-out mechanism.
Background
In the production process of toughened glass, stress spots (commonly called wind spots) are often left on the heated glass in the toughening process due to uneven air blowing, the wind spots of the toughened glass are taken as an index of appearance quality and are more and more concerned by people, and technicians in the industry adopt various modes such as accelerating the glass discharging speed, optimizing the air hole layout, transversely swinging an air grid and the like to reduce the wind spots as much as possible. However, the formation of wind spots is complicated, and in addition to the need for uniform cooling across the width of the apparatus, it is also important to eliminate the formation of wind spots along the length of the apparatus. So far, the wind spot of the toughening furnace is still a flaw of the toughened glass, and people expect a better wind spot weakening technology to ensure that the toughened glass has better appearance.
The flexible shaft bent toughened glass toughening furnace consists of an upper sheet table, a heating furnace, a forming toughening unit, a lower sheet table and the like, and all working sections are connected by conveying roller ways with equal-height horizontal conveying surfaces to form a production line.
When the glass tempering furnace works, glass is placed on the upper piece platform, the conveying roller way conveys the glass into the heating furnace, the glass is heated to a proper temperature, the glass is conveyed to the forming tempering unit through the roller way, the glass is bent into a required shape in the unit, then air blowing tempering cooling is carried out through the air grid in the unit to form tempered glass, and finally the tempered glass is conveyed to the lower piece platform through the roller way to complete a working cycle.
The present flexible shaft bending and tempering forming mode is mainly characterized by that the flexible shaft roller table is bent in the direction perpendicular to conveying direction, and two ends of the flexible shaft group parallelly-arranged are equipped with arc-changing mechanisms which are parallel to the flexible shaft roller table along its axial direction. Two ends of a plurality of main air supply pipelines are respectively fixed with toothed plates on the arc changing mechanisms at corresponding positions, and the flexible shafts are vertically arranged with the main air supply pipelines; the main air supply pipeline is alternately provided with air boxes corresponding to the gaps of the flexible shafts, the inner cavities of the air boxes are communicated with the main air supply pipeline, and air flow is blown to the curved glass to be tempered from the air outlets of the air boxes through the air boxes. In order to ensure that the air is uniformly blown in the bending process, the prior art mostly adopts a mode of arranging a row of air boxes on the section bar for blowing, and the rows of air boxes are distributed between the gaps of the flexible shaft roller way. The main reasons for the occurrence of stress spots are: by adopting the wind box and wind grid technology, obvious stress spot marks can be left on the glass due to gaps between the wind boxes, and the attractiveness and the using effect of the glass are seriously influenced.
When the continuous through flexible air grid is adopted to process curved glass in a toughening way, and air flow from the main air supply pipeline blows air from the air inlet of the flexible air grid to the toughened curved glass to be processed through the air outlet of the flexible air grid, the inner wall of the flexible air grid has a plurality of folds, so that fluid resistance can be generated; and because flexible air grid can take place little deformation when the during operation, some air outlets also can take place deformation, only give vent to anger with the air outlet of seting up from its outer wall, the jet direction, the velocity of flow, the flow of air current all have unordered unstability of certain degree, increase the defective percentage.
SUMMERY OF THE UTILITY MODEL
When the toughened curved glass is continuously run through the flexible air grid, the inner wall of the flexible air grid has a plurality of folds, so that fluid resistance is generated; only the air outlet is arranged on the outer wall of the air conditioner, and the spraying direction, the flow speed and the flow rate of the air flow are disordered and unstable to a certain degree. In order to solve the problem, the utility model provides an air-out mechanism of curved surface glass tempering air grid.
The air outlet mechanism of the curved glass toughened air grid is used for a flexible air grid, the flexible air grid is composed of one or more flexible air grid units, and the air outlet mechanism comprises a fluid smooth structure arranged on the inner wall of each flexible air grid unit and/or an air outlet airflow directional stable structure arranged on the outer wall of each flexible air grid unit; the fluid smooth structure is used for reducing resistance when air flows in the flexible air grid unit circulate, and the air outlet airflow directional stabilizing structure is used for restraining the direction of the sprayed air flow and enabling the flow speed and the flow of the air flow to be more uniform.
Further, the flexible air grid unit is a corrugated pipe, and the fluid smooth structure is a composite rubber layer and is used for filling the corrugated inner wall of the corrugated pipe into a smooth inner wall.
Further, the air outlet is located at the position where the outer diameter of the corrugated pipe is maximum.
Furthermore, the air outlet flow directional stabilizing structure is an independent air nozzle communicated with each air outlet hole, each independent air nozzle is of a tubular structure, one end of each independent air nozzle is in butt joint with the corresponding air outlet hole, and the other end of each independent air nozzle faces the glass to be processed.
Furthermore, the air outlet airflow directional stabilizing structure is a fixing piece which is arranged on the corrugated outer wall of the metal corrugated pipe and covers the air outlet hole, an air spraying hole corresponding to the air outlet hole is formed in the fixing piece, and the air spraying hole is communicated with the air outlet hole.
Furthermore, the number of the air outlet holes is two or more.
The air outlet mechanism provided by the technical scheme smoothes the airflow channel with a plurality of folds on the inner wall of the flexible air grid unit, so that the fluid resistance is reduced; and the additionally arranged independent air nozzle or the fixing piece can not deform, and stably guides the air flow ejected from the air outlet of the flexible air grid, so that the ejection direction, the flow speed and the flow of the air flow are regulated and controlled to be directional, orderly and stable to a certain degree.
Drawings
FIG. 1 is a schematic diagram of the assembly of a main air supply duct and a flexible air grid unit;
FIG. 2 is an axial longitudinal cut view of a flexible wind grid unit with a fluid smoothing structure;
FIG. 3 is a front view of a flexible air grid unit with independent air nozzles;
FIG. 4 is a schematic radial cross-section of FIG. 3;
FIG. 5 is a front view of a flexible wind grid unit with fasteners;
FIG. 6 is a schematic radial cross-section of FIG. 5;
reference numerals: the air supply device comprises a main air supply pipeline 1, a flexible air grid unit 2, an air outlet hole 22, a composite rubber layer 23, an independent air nozzle 24, a fixing piece 25 and an air injection hole 251.
Detailed Description
The technical solution of the present invention will be described clearly and completely with reference to the accompanying drawings, and obviously, the described embodiments are some, but not all embodiments of the present invention. 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.
In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.
In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.
When processing toughened glass, the main air supply duct 1 and the flexible air grid unit 2 are arranged as shown in fig. 1, and arc changing mechanisms are arranged at two ends of the main air supply duct (for the arc changing mechanisms, please refer to a glass bending forming mechanism in CN 201220306623.8). When the arc-changing mechanism is bent, the flexible wind grid unit 2 changes the radian along with the bending.
Example 1
An air outlet mechanism of a curved glass toughened air grid is arranged on a flexible air grid unit 2 and comprises a fluid smooth structure arranged on the inner wall of the flexible air grid unit 2 and/or an air outlet airflow directional stable structure arranged on the outer wall of the flexible air grid unit 2; the fluid smooth structure is used for reducing the resistance when the airflow circulates in the flexible air grid, and the air-out airflow directional stable structure is used for restraining the direction of the sprayed airflow and enabling the flow velocity and the flow of the airflow to be more uniform.
The fluid smooth structure and the outlet airflow directional stable structure can be alternatively arranged or cooperatively arranged.
Example 2
The present embodiment is further limited on the basis of embodiment 1, and the flexible air grid unit 2 is a corrugated pipe, and the material of the corrugated pipe may be metal or non-metal. The corrugated pipe is provided with an air outlet 22 facing the direction of the glass to be processed, and is also provided with an air supply outlet communicated with the main air supply pipeline 1. Referring to fig. 2, the fluid smoothing structure is a compound rubber layer 23 provided on the inner wall for filling the corrugated inner wall of the corrugated pipe with a smooth inner wall.
After the inner wall of the corrugated pipe is changed from being fully folded into a smooth inner wall, the internal fluid resistance is reduced, the wall thickness of the air outlet hole 22 is also increased, and the swing of the jet direction of the air flow is reduced.
The two axial ends of the flexible air grid unit 2 are of closed structures. The outer surface of the flexible wind fence unit 2 can withstand at least 150 ℃. The flexible air grid is a metal corrugated pipe.
Example 3
The embodiment is further limited on the basis of the embodiment 1, the flexible air grid unit 2 is a corrugated pipe, the corrugated pipe is provided with air outlet holes 22 facing the direction of the glass to be processed, and the corrugated pipe is also provided with an air supply opening communicated with the main air supply pipeline 1. Referring to fig. 3, the outlet hole 22 is located where the outside diameter of the corrugations of the bellows is the largest. The outlet airflow directional stabilizing structure is an independent air nozzle 24 communicated with each air outlet hole 22, the independent air nozzle 24 is of a tubular structure, one end of the independent air nozzle is in butt joint with the air outlet holes 22, and the other end faces towards the glass substitute. Referring to fig. 4, each pleat has 2-4 vent holes 22 toward the glass to be machined. The connection mode of the independent air nozzle 24 and the corrugated pipe is threaded connection, riveting or welding.
The independent air nozzle 24 is made of a material which is not easy to deform, and when the flexible air grid unit 2 deforms due to the arc-variable mechanism, the inner diameter of the independent air nozzle 24 cannot deform, so that the air direction is determined while the air is more stable during air injection.
Example 4
The present embodiment is further limited on the basis of embodiment 1, and is a parallel embodiment of embodiment 3, the flexible air grid is a corrugated pipe, the corrugated pipe is provided with an air outlet 22 facing the direction of the glass to be processed, and the corrugated pipe is further provided with an air supply outlet communicated with the main air supply pipeline 1. The air outlet 22 is located where the outside diameter of the corrugations of the bellows is the largest. Referring to fig. 6, the number of the air holes 22 is two or more, the outlet airflow directional stabilization structure is a fixing member 25 covering the air outlet hole and located on the corrugated outer wall of the corrugated pipe, referring to fig. 5, the fixing member 25 is provided with an air injection hole 251 corresponding to the air outlet hole 22, and the air injection hole 251 is communicated with the air outlet hole 22. The fixing member 25 is connected to the bellows by riveting, welding or screwing.
The fixing member 25 is made of a material which is not easy to deform, when the flexible air grid unit 2 deforms due to the arc-changing mechanism, the diameters of the air injection holes 251 on the fixing member 25 are not changed, and the fixing member 25 is provided with the plurality of air injection holes 251, so that all the air injection holes 251 on one fixing member 25 are relatively fixed during air injection, and the air direction is determined while the air flow is more stable. The air outlet is arranged in a rivet riveting mode. The aperture of the air outlet is 2-10 mm.
The two axial ends of the flexible air grid unit 2 are of a closed structure so as to ensure that air flow can only be blown out through the air outlet holes in the flexible air grid unit 2; the flexible air grid unit 2 with a through inner part and a closed end part can be directly and integrally manufactured during production; or the main structure of the flexible air grid unit 2 and the end part can be combined in a split manner, the main structure of the flexible air grid unit 2 with the end part not closed is firstly manufactured, and then the end part is sealed at the two axial ends in a plug, bolt, cover plate and other manners.
The technical solutions of the embodiments 2, 3 and 4 can be implemented in cooperation in any combination.
It should be noted that the reference means in the claims are not limited to the reference relationships, and those skilled in the art can freely combine the dependent claims in the knowledge of the present specification, and it is within the protection scope of the present invention to include all the embodiments corresponding to the permutation and combination.
Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the embodiments of the present invention.
Claims (6)
1. The air outlet mechanism of the curved glass tempering air grid is characterized in that the air outlet mechanism is used for a flexible air grid; the flexible air grid consists of one or more flexible air grid units, and the air outlet mechanism comprises a fluid smooth structure arranged on the inner wall of the flexible air grid unit and/or an air outlet airflow directional stable structure arranged on the outer wall of the flexible air grid unit; the fluid smooth structure is used for reducing resistance when air flows in the flexible air grid unit circulate, and the air outlet airflow directional stabilizing structure is used for restraining the direction of the sprayed air flow and enabling the flow speed and the flow of the air flow to be more uniform.
2. The air outlet mechanism of the curved glass tempering air grid according to claim 1, wherein the flexible air grid unit is a corrugated pipe, and the fluid smooth structure is a composite rubber layer for filling the corrugated inner wall of the corrugated pipe with a smooth inner wall.
3. The air outlet mechanism of the curved glass tempering air grid according to claim 2, wherein an air outlet is positioned at the position where the outer diameter of the corrugation of the corrugated pipe is maximum.
4. The air outlet mechanism of the curved glass tempering air grid according to claim 3, wherein said air outlet flow direction stabilizing structure is an independent air nozzle communicated with each air outlet hole, said independent air nozzle is a tubular structure, one end of the independent air nozzle is in butt joint with the air outlet hole, and the other end of the independent air nozzle faces to the glass to be processed.
5. The air outlet mechanism of the curved glass tempering air grid according to claim 3, wherein the air outlet flow directional stabilization structure is a fixing member arranged on the corrugated outer wall of the corrugated pipe and covering the air outlet hole, the fixing member is provided with an air outlet hole corresponding to the air outlet hole, and the air outlet hole is communicated with the air outlet hole.
6. The air outlet mechanism of the curved glass tempering air grid according to claim 4 or 5, wherein the number of the air outlet holes is two or more.
Priority Applications (1)
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CN201921206897.8U CN210506062U (en) | 2019-07-29 | 2019-07-29 | Air outlet mechanism of curved glass tempering air grid |
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CN201921206897.8U CN210506062U (en) | 2019-07-29 | 2019-07-29 | Air outlet mechanism of curved glass tempering air grid |
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CN210506062U true CN210506062U (en) | 2020-05-12 |
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CN201921206897.8U Active CN210506062U (en) | 2019-07-29 | 2019-07-29 | Air outlet mechanism of curved glass tempering air grid |
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