CN111423102A

CN111423102A - Transmission discharge structure of 3D hot bender

Info

Publication number: CN111423102A
Application number: CN202010212987.9A
Authority: CN
Inventors: 左洪波; 杨鑫宏; 李铁; 王玉平; 张广友
Original assignee: Harbin Aurora Optoelectronics Technology Co Ltd
Current assignee: Harbin Aurora Optoelectronics Technology Co Ltd
Priority date: 2020-03-24
Filing date: 2020-03-24
Publication date: 2020-07-17

Abstract

The invention provides a transmission discharging structure of a 3D large-size hot bending machine, which comprises 1 set of double-shifting fork structure and 1 set of cooling discharging structure. The double-shifting fork structure penetrates through the furnace chamber, is symmetrically distributed on two sides and consists of 2 shifting fork shafts and 12 shifting forks; the sealed cooling cavity is connected to the outlet of the slow cooling station of the furnace cavity of the hot bending machine. The cooling discharge structure comprises a movable material receiving structure, a material pushing structure and a cooling structure. The invention can realize the stability of discharging the die, improve the production efficiency and ensure the service life of the die.

Description

Transmission discharge structure of 3D hot bender

Technical Field

The invention discloses a transmission discharging structure, and particularly relates to a transmission discharging structure of a 3D large-size hot bending machine.

Background

The hot bending glass is curved glass which is made by heating and softening plate glass in a mould, bending and molding under certain pressure and then annealing. With the progress of the industrial technical level and the improvement of aesthetic requirements of people, the application requirements on the 3D curved glass electronic product screen are higher and higher, the screen is not limited to a smart phone, and the 3D curved screen is added to the electronic product screen with larger size. For example, more and more tablet computers and vehicle-mounted computers adopt 3D curved screens, and are sought after by many consumers.

With the continuous increase of the demand of 3D glass, the development of the whole industrial chain is driven, and the demand of the 3D hot bending machine is also increased explosively as the core processing equipment for producing the 3D glass. The traditional hot bending machine transmission discharging structure is applied to a large-size hot bending machine, the structure is complex and unstable, the problems of blocking and the like often occur, the production beat and the maintenance frequency are greatly increased, and the production efficiency is reduced. Therefore, the research on the transmission discharging structure is very important.

Disclosure of Invention

The invention mainly aims at the problems that the traditional hot bending machine transmission discharging structure is applied to a large-size hot bending machine, the structure is complex and unstable, and jamming often occurs, and the like, and provides a transmission discharging structure of a 3D hot bending machine.

The purpose of the invention is realized as follows: the transmission discharging structure comprises 1 set of double-shifting fork structure and 1 set of cooling discharging structure, wherein the double-shifting fork structure penetrates through the furnace chamber, is symmetrically distributed on two sides and consists of 2 shifting fork shafts and 12 shifting forks; the sealed cooling cavity is connected to the outlet of the slow cooling station of the hot bending machine furnace cavity, and the cooling discharging structure comprises a movable material receiving structure, a material pushing structure, a cooling structure and the like. The invention can realize the stability of discharging the die, improve the production efficiency and ensure the service life of the die.

The invention has the following beneficial effects:

1. the double-shifting fork structure is composed of two shifting fork shafts on two sides of the equipment and paired short shifting forks on the shifting fork shafts, the shifting fork shafts are arranged on two sides of stations in the hearth, and the short shifting forks are uniformly arranged between the stations, so that the two sides can move and shift materials simultaneously.

2. The bottom plate of the sealed cooling cavity adopts a movable material receiving structure, the mold is conveyed into the sealed cooling cavity from the furnace cavity, the mechanical structure is simple, the action is stable, and the mold is not blocked.

The discharging side of the sealed cooling cavity is connected with the movable material receiving platform, the movable material receiving platform is connected with the operating platform, stable discharging can be realized, and the mold is safely conveyed to the operating platform through the material pusher.

Drawings

FIG. 1 is a top view of a dual fork structure of the present invention;

FIG. 2 is a top view of the cooling and discharging structure of the present invention.

Detailed Description

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

Referring to fig. 1, the present embodiment includes 1 set of double-shifting fork structure and 1 set of cooling discharging structure, the double-shifting fork structure penetrates through the furnace chamber, is symmetrically distributed on two sides, and is composed of 2 shifting fork shafts and 12 shifting forks; the sealed cooling cavity is connected to the outlet of the slow cooling station of the furnace cavity of the hot bending machine. The cooling discharging structure comprises a movable material receiving structure, a material pushing structure, a cooling structure and the like. The transmission discharging structure comprises a double-shifting fork structure,

the double-fork structure is composed of two

fork shafts

13 and 15 on two sides of the equipment, and a pair of

short forks

12 and 14 on the fork shafts. The shifting fork shafts are arranged on two sides of the stations in the hearth, and the short shifting forks are uniformly arranged among the stations, as shown in the attached drawing.

When the equipment normally operates, the feeding door pushes the material cylinder 16 to send the die to the position of the station 1. The swing cylinder drives the shifting fork shaft to rotate and fall down, the motor pushes the shifting fork shaft to move forwards to drive the shifting fork to shift the mold forwards to a station, then the swing cylinder drives the shifting fork shaft to rotate back to the original position, and the motor rotates back to return the shifting fork to the original position.

So far, the whole material shifting process is completed, and in the whole action process, the shifting fork and the shifting fork shaft are relatively static.

With reference to fig. 2, the cooling discharge device is composed of a fork shaft, a fork, a cylinder, a cooling bottom plate, a motor and the like, and the structure is as shown in fig. 2. The shifting fork shaft 1 is connected with the shifting fork 2, the cylinder 4 is connected with the cooling bottom plate 3, the motor is connected with the movable material receiving platform 6, and the shifting fork shaft 1, the first discharge door 10, the second discharge door 11, the motor, the cylinder 4, the cylinder 7 and the cylinder 8 are all connected with the control system.

The shifting fork shaft 1 drives the shifting fork 2 to shift the mold to 6 stations, the discharge door I10 rises, the cylinder 4 extends out to enable the cooling bottom plate 3 to enter a furnace chamber and be connected with the 6 station lower heating plate, the shifting fork 2 shifts the mold to the cooling bottom plate 3, the cylinder 4 drives the cooling bottom plate 3 to withdraw, at the moment, the mold enters the sealed cooling cavity 5, and the discharge door I10 descends to start cooling. After the beat, the second discharge door 11 rises, and the motor drives to remove and connects material platform 6 to remove to second discharge door 11, and cylinder 7 stretches out, pushes away the mould to remove to connect material platform 6 on, and cylinder 7 withdraws, and the motor drives to remove and connects material platform 6 to return the normal position, and second discharge door 11 descends. The cylinder 8 extends out, the mould is pushed to the operating platform 9, the cylinder is retracted, and all transmission discharging processes are completed. The shifting fork shaft 1, the first discharge door 10, the second discharge door 11, the motor, the cylinder 4, the cylinder 7 and the cylinder 8 are all connected with a control system, and the operation is realized by the control system.

The foregoing is a more detailed description of the invention and is not intended to limit the invention to the particular form disclosed. Variations and modifications of the present invention may become apparent to those of ordinary skill in the art to which the invention pertains, and such variations and modifications are to be considered within the scope of the invention as defined by the appended claims.

Claims

1. A transmission discharging structure of a 3D hot bending machine is characterized by comprising 1 set of double shifting fork structure and 1 set of cooling discharging structure, wherein the double shifting fork structure penetrates through the inside of a furnace chamber, is symmetrically distributed on two sides and consists of 2 shifting fork shafts and 12 shifting forks; the sealed cooling cavity is connected to the outlet of the slow cooling station of the hot bending machine furnace cavity, and the cooling discharging structure comprises a movable material receiving structure, a material pushing structure, a cooling structure and the like.

2. The transmission discharging structure of 3D hot bending machine according to claim 1, wherein the double-fork structure is symmetrically distributed on two sides of the furnace chamber, so that the two sides simultaneously move and kick-off the material, thereby avoiding the position distortion of the mold during moving and kick-off the material.

3. The transmission discharging structure of the 3D hot bending machine according to claim 2, wherein the bottom plate of the sealed cooling cavity adopts a movable material receiving structure to convey the mold from the furnace cavity into the sealed cooling cavity, the mechanical structure is simple, the operation is stable, and the mold blocking phenomenon cannot occur.

4. The transmission discharging structure of 3D hot bending machine according to claim 3, wherein the discharging side of the sealed cooling cavity is connected with a movable material receiving platform, the movable material receiving platform is connected with the operating platform, so that stable discharging can be realized, and the mold can be safely conveyed to the operating platform through the material pusher.

5. The transmission discharging structure of the 3D hot bending machine according to claim 4, wherein the cooling discharging structure comprises a shifting fork shaft, a shifting fork, a cylinder, a cooling bottom plate and a motor, the shifting fork shaft is connected with the shifting fork, the cylinder is connected with the cooling bottom plate, and the motor is connected with the movable material receiving platform.