CN220845911U - Cooling device for tempered glass processing - Google Patents

Abstract

The utility model provides a cooling device for tempered glass processing, which belongs to the technical field of glass processing and comprises a bracket and a plurality of support rods arranged on the bracket, wherein a support frame is arranged between the support rods, an air storage chamber is arranged on the support frame, an air inlet pipe is arranged at the top of the air storage chamber, a plurality of air outlets are arranged at the bottom of the air storage chamber in an array manner corresponding to the air inlet pipe, a plurality of support pipes are also arranged in the bracket through bearings, the end parts of the support pipes are in transmission connection, a pipeline frame is arranged on the side edge of the bracket, a plurality of air supply pipes are arranged on the pipeline frame, one end of each air supply pipe is connected with the end part of the support pipe through a bearing, the other end of each air supply pipe is connected with the air storage chamber, and a plurality of air outlets are arranged on each support pipe; the utility model can continuously cool the upper and lower surfaces of the glass, thereby increasing the efficiency of glass processing.

Description

Cooling device for tempered glass processing

Technical Field

The utility model relates to the technical field of glass processing equipment, in particular to a cooling device for tempered glass processing.

Background

Glass is an amorphous inorganic nonmetallic material, which is generally prepared by taking various inorganic minerals as main raw materials and adding a small amount of auxiliary raw materials.

The toughened glass is formed by putting ordinary glass into a heating furnace for quenching and softening, and conveying the softened glass into a cooling device for quenching and cooling after heating, and the toughened glass is prestressed glass, has the advantages of high impact strength, high use safety, high thermal stability and the like, and is widely used in various industries, and toughened glass processing equipment is required for producing the toughened glass. The "cooling process" of the glass is an important part of the tempering process.

Publication No. CN202122567904.0 is a cooling device for glass working; although this apparatus can cool glass, it can cool glass only in batches, and cannot cool glass continuously.

Disclosure of utility model

In view of the above, the present utility model provides a cooling device for processing tempered glass, which can continuously cool both upper and lower surfaces of glass, thereby increasing efficiency of glass processing.

In order to solve the technical problems, the utility model provides a cooling device for tempered glass processing, which comprises a bracket and a plurality of support rods arranged on the bracket, wherein the support rods are vertically arranged on the bracket, a support frame is arranged between the support rods, the support rods can provide support for the support frame, an air storage chamber is arranged on the support frame, cold air is stored in the air storage chamber, an air inlet pipe is arranged at the top of the air storage chamber, the cold air can enter the air storage chamber through the air inlet pipe, a plurality of air outlets are arranged at the bottom of the air storage chamber in an array manner corresponding to the air inlet pipe, the cold air in the air storage chamber can be discharged through the air outlets, a plurality of support pipes are also arranged in the bracket through bearings, the support pipes can rotate in the bracket, the end parts of the plurality of support pipes are in transmission connection, the plurality of support pipes can rotate simultaneously, a pipeline frame is arranged on the side edge of the bracket, one end part of the pipeline frame can provide support for the plurality of air supply pipes, one end parts of the air supply pipes are connected with the support pipes through bearings, the other end parts of the air supply pipes are connected with the air storage chamber, the cold air in the air storage chamber can enter the support pipes, a plurality of air outlets are arranged on each support pipe, and the cold air in the air storage chamber can be discharged through the air outlets.

A rubber layer is arranged on the outer side of the supporting tube; i.e. the rubber layer can increase the friction between the support tube and the glass.

A filter screen is arranged in the air outlet hole; i.e. the screen prevents glass fragments from entering the support tube.

The end part of each supporting tube is provided with a first belt pulley, every two adjacent first belt pulleys are connected through a belt, a plurality of supporting tubes can rotate simultaneously, the side edge of each support is also provided with a motor frame, a driving motor is arranged on the motor frame, the motor frame provides support for the driving motor, the output shaft of the driving motor is provided with a second belt pulley, and the second belt pulley is connected with the first belt pulley at the most end part through the belt; i.e. the driving motor can indirectly drive the supporting tubes to rotate.

A stop block is arranged below the bracket, and a groove is arranged on the stop block corresponding to the bracket; i.e. glass fragments can fall into the grooves.

A guide hole is formed in the stop block corresponding to the groove, and a receiving plate is arranged in the guide hole in a sliding manner; namely, the material receiving plate can receive the glass in the groove.

In summary, compared with the prior art, the application has at least one of the following beneficial technical effects:

1. The glass is placed on the support tubes on the support, then the support tubes are controlled to convey the glass, and cold air can be indirectly blown to the glass through the air outlet and the air outlet by inputting the cold air into the air storage chamber through the air inlet pipe, so that the glass can be continuously cooled, and the glass processing efficiency is increased.

2. Because the internal medium is unevenly distributed when part of glass is manufactured, the glass can be cracked when being cooled after being heated, and the glass can fall into the groove after being cracked, thereby being convenient for collecting glass fragments.

Drawings

FIG. 1 is a schematic structural view of a cooling device for tempered glass processing according to the present utility model;

FIG. 2 is a schematic structural diagram of a side view of the present utility model;

Fig. 3 is a schematic diagram of the structure of fig. 2a according to the present utility model.

Reference numerals illustrate:

100. A bracket; 101. a support rod; 102. a support frame; 103. an air storage chamber; 104. an air inlet pipe; 105. an air outlet; 106. a support tube; 107. a pipe rack; 108. an air supply pipe; 109. an air outlet hole;

200. a first pulley; 201. a motor frame; 202. a driving motor; 203. a second pulley;

300. A stop block; 301. a groove; 302. a guide hole; 303. and a receiving plate.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present utility model more clear, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to fig. 1 to 3 of the embodiments of the present utility model. It will be apparent that the described embodiments are some, but not all, embodiments of the utility model. All other embodiments, which are obtained by a person skilled in the art based on the described embodiments of the utility model, fall within the scope of protection of the utility model.

As shown in fig. 1-3: the embodiment provides a cooling device for toughened glass processing, which comprises a bracket 100 and a plurality of support rods 101 vertically arranged on the bracket 100, wherein a plurality of support tubes 106 are arranged on the bracket 100 through bearings, a plurality of support tubes 106 are distributed on the bracket 100 in a linear array, two ends of each support tube 106 are connected with the bracket 100 through bearings, the support tubes 106 can rotate on the bracket 100, the air inlet tubes 104 are connected with an external refrigeration mechanism, namely the refrigeration mechanism can convey cold air into the air inlet tubes 104 and then enter the air storage chamber 103 through the air inlet tubes 104, the bottom of the air storage chamber 103 is also provided with a plurality of air outlets 105, namely the cold air in the air storage chamber 103 can be blown to the upper surface of glass through a plurality of air outlets 105, the plurality of support tubes 106 are distributed on the bracket 100 in a linear array, the two ends of each support tube 106 are connected with the bracket 100 through bearings, the support tubes 106 can rotate on the bracket 100, namely the plurality of support tubes 106 can rotate simultaneously, the glass can be conveyed, the corresponding plurality of support tubes 106 are arranged on the side edges of the bracket 100, the pipeline racks 107 are arranged, and the air outlet holes 109 can not be connected with the air outlet holes 109 through the plurality of support tubes, namely the air outlet holes 109 can be connected with the air storage tubes 106 in the air storage chamber;

The glass to be cooled is sequentially placed on the support tubes 106 on the support 100, then the support tubes 106 are controlled to rotate on the support 100, the support tubes 106 can drive the glass to move on the support 100, and meanwhile, external cold air is controlled to enter the air storage chamber, so that part of cold air is blown to the upper surface of the glass through the multiple rows of air outlets, the glass is cooled, part of cold air enters the support tubes 106 through the air supply pipes 108, the cold air in the support tubes 106 can be blown to the lower surface of the glass through the air outlet holes 109, the glass is cooled, namely, the upper surface and the lower surface of the glass can be cooled simultaneously, the glass can be cooled continuously, the completion of the cooling of the glass in batches is not required, and the processing efficiency of the glass is improved.

A rubber layer is arranged on the outer side of the supporting tube 106; the rubber layer can increase the friction between the support tube and the lower surface of the glass, so that the support tube can rotate to drive the glass to move on the support 100, the glass is prevented from slipping on the support tube 106, and the support tube 106 can be prevented from grinding the lower surface of the glass when the support tube 106 rotates under the glass.

A filter screen is arranged in the air outlet hole 109; the filter screen can prevent external dust and sundries from entering the supporting tube 106 through the air outlet 109 to form blockage.

The pulley is as shown in figure 3,

The end of each supporting tube 106 far away from the air supply tube 108 is provided with a first belt pulley 200, each two adjacent first belt pulleys 200 are connected through a belt, namely, a plurality of supporting tubes 106 can rotate simultaneously with the belt through the first belt pulleys 200, the side edge of the bracket 100 is also fixed with a motor frame 201 through bolts, a driving motor 202 is fixedly arranged on the motor frame 201, an output shaft of the driving motor 202 is provided with a second belt pulley 203, and the second belt pulley 203 is connected with one first belt pulley 200 nearest to the driving motor 202 through the belt;

After the glass is placed on the support tubes 106, the driving motor 202 on the motor frame 201 is controlled to work, so that the output shaft of the driving motor 202 drives the second belt pulley 203 to rotate, the second belt pulley 203 can drive the first belt pulley 200 at the end part to rotate through the belt, the first belt pulleys 200 can simultaneously rotate through the belt, the first belt pulleys 200 can drive the support tubes 106 to simultaneously rotate, and the support tubes 106 can drive the glass to move.

The stop 300 is shown in figures 1-3,

A stop block 300 is further arranged below the support 100, the stop block 300 is positioned right below the support tubes 106, and a groove 301 is formed in the stop block 300 corresponding to the support 100; that is, due to the uneven distribution of the internal medium during the manufacture of a part of the glass, the glass may be cracked when being cooled after being heated, and the glass may fall into the groove 301 after being cracked, thereby facilitating the collection of glass fragments.

The guide holes 302 are shown in figure 2,

A guide hole 302 is formed in the stop block 300 corresponding to the groove 301, the guide hole 302 is communicated with the groove 301, and a receiving plate 303 is arranged in the guide hole 302 in a sliding manner; that is, the glass cullet falling into the groove 301 falls into the receiving plate 303, and the receiving plate 303 is pulled out from the guide hole 302 when the glass cullet is taken out.

Furthermore, it should be noted that, in the description of the present utility model, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model can be understood by those skilled in the art according to the specific circumstances.

While the foregoing is directed to the preferred embodiments of the present utility model, it will be appreciated by those skilled in the art that various modifications and adaptations can be made without departing from the principles of the present utility model, and such modifications and adaptations are intended to be comprehended within the scope of the present utility model.

Claims (6)

1. Cooling device is used in toughened glass processing, its characterized in that: including a plurality of bracing pieces (101) that support (100) and support (100) set up, set up braced frame (102) between a plurality of bracing pieces (101), set up reservoir (103) on braced frame (102), reservoir (103) top sets up air-supply line (104), and corresponding air-supply line (104) set up many exhaust openings (105) in reservoir (103) bottom array, still set up a plurality of stay tubes (106) through the bearing in support (100), a plurality of stay tube (106) tip transmission are connected, and support (100) side sets up pipeline frame (107), sets up a plurality of air supply pipe (108) on pipeline frame (107), air supply pipe (108) one end is connected with stay tube (106) tip through the bearing, the air supply pipe (108) other end is connected with reservoir (103), every all set up a plurality of ventholes (109) on stay tube (106).

2. The cooling device for tempered glass processing as claimed in claim 1, wherein: and a rubber layer is arranged on the outer side of the supporting tube (106).

3. The cooling device for tempered glass processing as claimed in claim 2, wherein: a filter screen is arranged in the air outlet hole (109).

4. A cooling device for tempered glass processing as claimed in claim 3, wherein: every stay tube (106) tip all sets up first belt pulley (200), is connected through the belt between every two adjacent first belt pulleys (200), support (100) side still sets up motor frame (201), set up driving motor (202) on motor frame (201), set up second belt pulley (203) on driving motor (202)'s the output shaft, second belt pulley (203) are connected through the belt with first belt pulley (200) of tip.

5. The cooling device for tempered glass processing as claimed in claim 4, wherein: a stop block (300) is further arranged below the support (100), and a groove (301) is formed in the stop block (300) corresponding to the support (100).

6. The cooling device for tempered glass processing as claimed in claim 5, wherein: and a guide hole (302) is formed in the stop block (300) corresponding to the groove (301), and a receiving plate (303) is arranged in the guide hole (302) in a sliding mode.