CN110539576A - Glass surface printing equipment for glass manufacturing - Google Patents

Abstract

The invention discloses glass surface printing equipment for glass manufacturing, which comprises an equipment box body, wherein a storage hopper and a lifting space are arranged in the equipment box body, a lifting plate is arranged in the lifting space, a supporting plate is arranged on the lifting plate, a pressing motor is started, the pressing motor drives a second pressing cylinder to rotate to flatten molten glass, when the flowing molten glass reaches the required amount, the electromagnet cylinder is reversely electrified, and pushes a permanent magnet and a cutter to cut off the molten glass.

Description

Glass surface printing equipment for glass manufacturing

Technical Field

The invention relates to the field of glass manufacturing, in particular to glass surface printing equipment for glass manufacturing.

background

when a plurality of buildings are built, a plurality of glass is used for decoration, and the surfaces of the glass used for decoration at present have a plurality of printed shapes, and the printed shapes not only have good aesthetic property, but also can obstruct the view.

At present, some glass printing devices are used for printing in a rolling printing mode, although the printing efficiency can be improved quickly, the glass liquid is always in a high-temperature state, the shape of the pressed flower cannot be automatically maintained, the printing effect is poor, when the glass is finally cut, a large amount of waste materials need to be cut off, the cost waste is serious, and the surface of the glass is rough after the glass is manufactured.

Disclosure of Invention

The invention aims to provide glass surface printing equipment for glass manufacturing, which is used for overcoming the defects in the prior art.

According to the embodiment of the invention, the glass surface printing equipment for glass manufacturing comprises a device box body, wherein a storage hopper and a lifting space are arranged in the device box body, a lifting plate is arranged in the lifting space, a supporting plate is arranged on the lifting plate, a conveying mechanism capable of conveying molten glass and the supporting plate is arranged in the storage hopper and the lifting space, the conveying mechanism comprises a discharge port arranged at the bottom wall of the storage hopper and communicated with the storage hopper, a pressing cylinder space and a magnet space are arranged in the discharge port and communicated with the discharge port, a second pressing cylinder capable of flattening the molten glass is rotatably arranged in the pressing cylinder space, a cutting knife capable of cutting the glass is slidably arranged in the magnet space, a conveying cylinder space with an upward opening is arranged on a boss at the right side of the device box body, and a printing mechanism capable of printing the glass is arranged in the conveying cylinder space,

The stamping mechanism comprises a first transfer cylinder and a second transfer cylinder which are rotatably arranged in the transfer cylinder space, a conveyor belt is arranged in front of the second conveying cylinder and the first conveying cylinder in a transmission way, the conveying mechanism conveys the supporting plate to the conveyor belt to receive the molten glass flowing down from the discharge hole, the top surface of a boss at the right side of the box body of the device is fixedly provided with an impression table, a sliding shaft is arranged on the impression table in a sliding way, the sliding shaft is rotatably provided with a first pressing cylinder, the first pressing cylinder can press glass to control the thickness of the glass, the stamping station is fixedly arranged in the stamping table, the piston push rod is fixedly connected with a hydraulic cylinder shaft, a pressing block is fixedly arranged on the hydraulic cylinder shaft, the embossing die is fixedly installed on the pressing block, and the pressing block can completely remove redundant glass around the supporting plate when the pressing block is used for embossing the glass.

on the basis of the technical scheme, the conveying mechanism further comprises a pressing motor arranged in the inner wall of the rear side of the discharge port, an output shaft of the pressing motor is fixedly connected with the second pressing cylinder, an electromagnet is fixedly installed in the top wall of the magnet space, a permanent magnet is fixedly installed on the top surface of the cutting knife, and a sliding plate is fixedly installed on the lower side of the discharge port and positioned on the right side surface of the device box body.

On the basis of the technical scheme, the inner wall of the rear side of the lifting space is provided with a lifting motor communicated with the rear side face of the device box body, the bottom wall of the lifting space is fixedly provided with the lifting motor, the output shaft of the lifting motor is fixedly connected with a threaded shaft, the lifting plate is provided with a lifting plate in a threaded manner and is in sliding connection with the lifting space, the inner wall of the left side of the lifting space is fixedly provided with a limit controller, the lifting plate can be provided with a supporting plate, and the limit controller can detect the height of the position of the supporting plate.

On the basis of the technical scheme, a pushing space communicated with the lifting space is arranged on the top wall of the lifting space, a belt wheel cavity is arranged on the rear side of the pushing space, a conveying motor is fixedly installed in the inner wall of the rear side of the belt wheel cavity, a first belt wheel shaft is fixedly installed on an output shaft of the conveying motor and penetrates through the belt wheel cavity and the pushing space, a third conveying cylinder is fixedly installed on the first belt wheel shaft and is located on the pushing space, a fourth conveying cylinder is rotatably installed between the front inner wall and the rear inner wall of the pushing space, a rubber conveying belt is installed between the fourth conveying cylinder and the third conveying cylinder in a transmission mode, and the rubber conveying belt has elasticity.

on the basis of the technical scheme, the stamping mechanism further comprises a second belt wheel shaft which is rotatably arranged between the belt wheel cavity and the space of the conveying cylinder, the second belt wheel shaft is fixedly connected with the first conveying cylinder, a second belt wheel is fixedly arranged on the second belt wheel shaft, a first belt wheel is fixedly arranged on the first belt wheel shaft, and the first belt wheel and the second belt wheel are in transmission installation.

on the basis of the technical scheme, a supporting table is fixedly arranged between the front inner wall and the rear inner wall of the space of the conveying cylinder.

On the basis of the technical scheme, sliding rods are fixedly installed on the top surface of the pressing block in a bilateral symmetry mode, the sliding rods penetrate through the pressing table upwards and are installed in a sliding mode with the pressing table, and adjusting nuts are installed on the sliding rods in a threaded mode.

On the basis of the technical scheme, the impressing platform is rotatably provided with the rotating wheel, and the rotating wheel and the sliding shaft are in threaded installation.

On the basis of the technical scheme, the air blowers are fixedly arranged on the imprinting station in a bilateral symmetry mode, and the placing station is fixedly arranged on the right side face of the right boss of the device box body.

The invention has the beneficial effects that: the invention can put the glass on the supporting plate for imprinting, each piece of glass can be supported by one supporting plate, the imprinting is convenient, the rapid cooling can be realized, the carrying is very convenient,

The size of the glass manufactured is controlled by controlling the amount of each glass liquid, the thickness of the glass can be adjusted, when the glass is imprinted, the surface of the glass can be printed, the shape of the glass can be processed at one time, and the glass is quickly molded and worth being popularized.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic sectional view taken along the line A-A in FIG. 1;

FIG. 3 is a schematic sectional view taken along line B-B in FIG. 1;

Fig. 4 is an enlarged schematic view of the structure at C in fig. 1.

Detailed Description

The invention will now be described in detail with reference to fig. 1-4, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, front and rear directions described below correspond to the front, back, left, right, top and bottom directions of the view direction of fig. 1, fig. 1 is a front view of the apparatus of the present invention, and the directions shown in fig. 1 correspond to the front, back, left, right, top and bottom directions of the apparatus of the present invention.

Referring to fig. 1 to 4, a glass surface printing apparatus for glass manufacturing according to an embodiment of the present invention includes an apparatus box 10, a storage hopper 26 and a lifting space 16 are provided in the apparatus box 10, a lifting plate 14 is provided in the lifting space 16, a supporting plate 15 is disposed on the lifting plate 14, a conveying mechanism 80 capable of conveying molten glass and the supporting plate 15 is provided in the storage hopper 26 and the lifting space 16, the conveying mechanism 80 includes a discharge port 25 provided at a bottom wall of the storage hopper 26 and communicated with the storage hopper 26, a pressing cylinder space 47 and a magnet space 55 are provided in the discharge port 25 and communicated with the discharge port 25, a second pressing cylinder 48 capable of flattening the molten glass is rotatably installed in the pressing cylinder space 47, a cutting knife 58 capable of cutting glass is slidably installed in the magnet space 55, a boss on a right side of the apparatus box 10 is provided with a conveying cylinder space 40 having an upward opening, an embossing mechanism 81 capable of embossing glass is arranged in the conveying cylinder space 40,

The pressing mechanism 81 comprises a first conveying cylinder 45 and a second conveying cylinder 41 which are rotatably installed in the conveying cylinder space 40, a conveying belt 43 is installed in front of the second conveying cylinder 41 and the first conveying cylinder 45 in a transmission manner, the conveying mechanism 80 conveys the supporting plate 15 onto the conveying belt 43 to receive the glass liquid flowing down from the discharge port 25, a pressing table 27 is fixedly installed on the top surface of a right boss of the device box body 10, a sliding shaft 29 is installed on the pressing table 27 in a sliding manner, a first pressing cylinder 31 is installed on the sliding shaft 29 in a rotating manner, the first pressing cylinder 31 can press the glass to control the thickness of the glass, a 32 is fixedly installed in the pressing table 27, a piston push rod of the 32 is fixedly connected with a hydraulic cylinder shaft 33, a pressing block 36 is fixedly installed on the hydraulic cylinder shaft 33, an embossing die 37 is fixedly installed on the pressing block 36, and the pressing block 36 can press the glass, and completely removing the redundant glass around the supporting plate 15.

In addition, in one embodiment, the conveying mechanism 80 further includes a pressing motor 49 disposed in the inner wall of the rear side of the discharging hole 25, the output shaft of the pressing motor 49 is fixedly connected with the second pressing cylinder 48, an electromagnet 56 is fixedly arranged in the top wall of the magnet space 55, the top surface of the cutting knife 58 is fixedly provided with a permanent magnet 57, the right side surface of the device box 10 is fixedly provided with a sliding plate 24 positioned at the lower side of the discharge hole 25, when the glass liquid entering the storage hopper 26 passes through the discharge hole 25, electrifying the electromagnet 56, attracting the permanent magnet 57, making the cutoff knife 58 slide upwards, making the glass liquid pass through the discharge hole 25, starting the pressing motor 49, the pressing motor 49 driving the second pressing cylinder 48 to rotate to flatten the glass liquid, when the outflow glass liquid reaches the required amount, when the electromagnet 56 is energized in the opposite direction, the electromagnet 56 pushes the permanent magnet 57 and the cutter 58 to cut off the molten glass.

In addition, in an embodiment, a rear inner wall of the lifting space 16 is provided with a position communicating with the rear side of the device case 10, a lifting motor 11 is fixedly installed on the bottom wall of the lifting space 16, a threaded shaft 13 is fixedly connected to an output shaft of the lifting motor 11, a lifting plate 14 is threadedly installed on the lifting plate 14, the lifting plate 14 is slidably connected to the lifting space 16, a limit controller 18 is fixedly installed on the left inner wall of the lifting space 16, a supporting plate 15 can be placed on the lifting plate 14, the limit controller 18 can detect the height of the position of the supporting plate 15, when the supporting plate 15 is sent out, the limit controller 18 controls to start the lifting motor 11, the lifting motor 11 drives the threaded shaft 13 to rotate, so that the lifting plate 14 moves upwards, and pushes the supporting plate 15 to the height of the position of the limit controller 18.

In addition, in one embodiment, a pushing space 20 communicated with the lifting space 16 is provided on a top wall of the lifting space 16, a pulley cavity 51 is provided at a rear side of the pushing space 20, a conveying motor 50 is fixedly installed in an inner wall at the rear side of the pulley cavity 51, a first pulley shaft 23 is fixedly installed on an output shaft of the conveying motor 50, the first pulley shaft 23 penetrates through the pulley cavity 51 and the pushing space 20, a third conveying cylinder 22 is fixedly installed on the first pulley shaft 23 on the pushing space 20, a fourth conveying cylinder 21 is rotatably installed between the front inner wall and the rear inner wall of the pushing space 20, a rubber conveying belt 19 is installed between the fourth conveying cylinder 21 and the third conveying cylinder 22 in a transmission manner, the rubber conveying belt 19 has elasticity, and when the lifting plate 14 lifts the supporting plate 15 up, the conveying motor 50 is started, the conveying motor 50 drives the first pulley shaft 23 to rotate, the rotation of the first pulley shaft 23 drives the third conveying cylinder 22 to rotate, the rotation of the third conveying cylinder 22 drives the rubber conveying belt 19 to rotate, and the rubber conveying belt 19 can drive the supporting plate 15 to convey out to the right.

In addition, in one embodiment, the stamping mechanism 81 further includes a second pulley shaft 46 rotatably installed between the pulley cavity 51 and the conveying cylinder space 40, the second pulley shaft 46 is fixedly connected to the first conveying cylinder 45, a second pulley 54 is fixedly installed on the second pulley shaft 46, a first pulley 52 is fixedly installed on the first pulley shaft 23, a transmission installation 53 is installed between the first pulley 52 and the second pulley 54, after the conveying motor 50 is started, the conveying motor 50 drives the first pulley 52 to rotate, the first pulley 52 drives the second pulley 54 to rotate, the second pulley 54 drives the first conveying cylinder 45 to rotate, and the first conveying cylinder 45 rotates to drive the pallet 15 conveyed to the conveying belt 43 to continue conveying to the right.

in addition, in one embodiment, a support table 44 is fixedly installed between the front and rear inner walls of the transfer drum space 40, and the support table 44 can support the glass while the glass is continuously pressed.

in addition, in one embodiment, slide rods 34 are fixedly mounted on the top surface of the pressing block 36 in a bilateral symmetry manner, the slide rods 34 upwardly penetrate through the stamping table 27 and are slidably mounted with the stamping table 27, adjusting nuts 35 are screwed on the slide rods 34, and the up-and-down stamping stroke of the pressing block 36 can be adjusted by rotating the adjusting nuts 35.

In addition, in one embodiment, a rotating wheel 28 is rotatably mounted on the stamping station 27, the rotating wheel 28 is screwed with the sliding shaft 29, and the first pressing cylinder 31 can adjust the thickness of the glass up and down by rotating the rotating wheel 28.

In addition, in one embodiment, the air blower 30 is fixedly mounted on the embossing station 27 in a left-right symmetrical manner, the placing station 39 is fixedly mounted on the right side surface of the right boss of the device case 10, the glass which is embossed can be received by the placing station 39, and the air blower 30 performs air blowing cooling.

Glass liquid is sent into the storage hopper 26, when the glass liquid entering the storage hopper 26 passes through the discharge hole 25, the electromagnet 56 is electrified to attract the permanent magnet 57, the cutoff knife 58 slides upwards, the glass liquid can pass through the discharge hole 25, the pressing motor 49 is started, the pressing motor 49 drives the second pressing cylinder 48 to rotate to flatten the glass liquid, when the glass liquid flowing out reaches the required amount, the electromagnet 56 is electrified reversely, the permanent magnet 57 and the cutoff knife 58 are pushed by the electromagnet 56 to cutoff the glass liquid,

The limit controller 18 starts the lifting motor 11 according to the height of the supporting plate 15 on the lifting plate 14, the lifting motor 11 drives the threaded shaft 13 to rotate, so that the lifting plate 14 moves upwards to push the supporting plate 15 to the position height of the limit controller 18, when the lifting plate 14 lifts the supporting plate 15, the conveying motor 50 is started, the conveying motor 50 drives the first pulley shaft 23 to rotate, the first pulley shaft 23 rotates to drive the third conveying cylinder 22 to rotate, the third conveying cylinder 22 rotates to drive the rubber conveying belt 19 to rotate, the rubber conveying belt 19 can drive the supporting plate 15 to convey outwards, so that the glass liquid on the discharge port 25 flows into the supporting plate 15,

The conveying motor 50 drives the first belt pulley 52 to rotate, the first belt pulley 52 rotates to drive the second belt pulley 54 to rotate, the second belt pulley 54 rotates to drive the first conveying cylinder 45 to rotate, the first conveying cylinder 45 rotates to drive the supporting plate 15 conveyed to the conveying belt 43 to continue conveying to the right to an embossing area, the pressing block 36 and the embossing die 37 are driven by the pressing block 32 to emboss glass on the supporting plate 15 downwards, the pressing stroke of the pressing block 36 up and down can be adjusted by rotating the adjusting nut 35, the thickness of the glass can be adjusted up and down by rotating the rotating wheel 28 so that the first pressing cylinder 31 can be adjusted up and down, the pressed glass can be received by the placing table 39, and the air blower 30 performs air blowing and cooling.

The invention has the beneficial effects that: the invention can put the glass on the supporting plate for imprinting, each piece of glass can be supported by one supporting plate, the imprinting is convenient, the rapid cooling can be realized, the carrying is very convenient,

The size of the glass manufactured is controlled by controlling the amount of each glass liquid, the thickness of the glass can be adjusted, when the glass is imprinted, the surface of the glass can be printed, the shape of the glass can be processed at one time, and the glass is quickly molded and worth being popularized.

It will be apparent to those skilled in the art that various modifications may be made to the above embodiments without departing from the general spirit and concept of the invention. All falling within the scope of protection of the present invention. The protection scheme of the invention is subject to the appended claims.

Claims (9)

1. The utility model provides a glass surface stamp equipment for glass preparation, includes the device box, its characterized in that: the glass printing device comprises a device box body, a storage hopper and a lifting space are arranged in the device box body, a lifting plate is arranged in the lifting space, a supporting plate is placed on the lifting plate, a conveying mechanism capable of conveying glass liquid and the supporting plate is arranged in the storage hopper and the lifting space, the conveying mechanism comprises a discharge port arranged on the bottom wall of the storage hopper and communicated with the storage hopper, a pressing cylinder space and a magnet space are arranged in the discharge port and communicated with the discharge port, a second pressing cylinder capable of flattening the glass liquid is rotatably arranged in the pressing cylinder space, a cutting knife capable of cutting the glass is slidably arranged in the magnet space, a conveying cylinder space with an upward opening is arranged on a boss on the right side of the device box body, and a stamping mechanism capable of printing the glass is arranged in the conveying cylinder space,

The stamping mechanism comprises a first transfer cylinder and a second transfer cylinder which are rotatably arranged in the transfer cylinder space, a conveyor belt is arranged in front of the second conveying cylinder and the first conveying cylinder in a transmission way, the conveying mechanism conveys the supporting plate to the conveyor belt to receive the molten glass flowing down from the discharge hole, the top surface of a boss at the right side of the box body of the device is fixedly provided with an impression table, a sliding shaft is arranged on the impression table in a sliding way, the sliding shaft is rotatably provided with a first pressing cylinder, the first pressing cylinder can press glass to control the thickness of the glass, the stamping station is fixedly arranged in the stamping table, the piston push rod is fixedly connected with a hydraulic cylinder shaft, a pressing block is fixedly arranged on the hydraulic cylinder shaft, the embossing die is fixedly installed on the pressing block, and the pressing block can completely remove redundant glass around the supporting plate when the pressing block is used for embossing the glass.

2. A glass surface embossing apparatus for glass making as claimed in claim 1, wherein: the conveying mechanism further comprises a pressing motor arranged in the inner wall of the rear side of the discharge port, an output shaft of the pressing motor is fixedly connected with the second pressing cylinder, an electromagnet is fixedly installed in the top wall of the magnet space, a permanent magnet is fixedly installed on the top surface of the cutting knife, and a sliding plate fixedly installed on the lower side of the discharge port is located on the right side surface of the device box body.

3. A glass surface embossing apparatus for glass making as claimed in claim 1, wherein: the lifting device is characterized in that the inner wall of the rear side of the lifting space is provided with a lifting motor which is communicated with the rear side face of the device box body, the bottom wall of the lifting space is fixedly provided with the lifting motor, the output shaft of the lifting motor is fixedly connected with a threaded shaft, the lifting plate is provided with a lifting plate in a threaded manner, the lifting plate is slidably connected with the lifting space, the inner wall of the left side of the lifting space is fixedly provided with a limit controller, the lifting plate can be provided with a supporting plate, and the limit controller can detect the height of the position of the supporting plate.

4. A glass surface embossing apparatus for glass making as claimed in claim 1, wherein: the rubber conveyor belt is characterized in that a pushing space communicated with the lifting space is arranged on the top wall of the lifting space, a belt wheel cavity is arranged on the rear side of the pushing space, a conveying motor is fixedly mounted in the inner wall of the rear side of the belt wheel cavity, a first belt wheel shaft is fixedly mounted on an output shaft of the conveying motor and penetrates through the belt wheel cavity and the pushing space, a third conveying cylinder is fixedly mounted on the pushing space on the first belt wheel shaft, a fourth conveying cylinder is rotatably mounted between the front inner wall and the rear inner wall of the pushing space, a rubber conveyor belt is mounted between the fourth conveying cylinder and the third conveying cylinder in a transmission mode, and the rubber conveyor belt has elasticity.

5. A glass surface embossing apparatus for glass making as claimed in claim 1, wherein: the stamping mechanism further comprises a second belt wheel shaft which is rotatably arranged between the belt wheel cavity and the space of the conveying cylinder, the second belt wheel shaft is fixedly connected with the first conveying cylinder, a second belt wheel is fixedly arranged on the second belt wheel shaft, a first belt wheel is fixedly arranged on the first belt wheel shaft, and the first belt wheel and the second belt wheel are in transmission installation.

6. A glass surface embossing apparatus for glass making as claimed in claim 1, wherein: and a supporting table is fixedly arranged between the front inner wall and the rear inner wall of the space of the conveying cylinder.

7. a glass surface embossing apparatus for glass making as claimed in claim 1, wherein: the stamping device is characterized in that slide rods are symmetrically and fixedly arranged on the top surface of the stamping block in a bilateral mode, the slide rods upwards penetrate through the stamping table and are slidably arranged on the stamping table, and adjusting nuts are arranged on the slide rods in a threaded mode.

8. A glass surface embossing apparatus for glass making as claimed in claim 1, wherein: and a rotating wheel is rotatably arranged on the impressing platform, and the rotating wheel and the sliding shaft are in threaded installation.

9. A glass surface embossing apparatus for glass making as claimed in claim 1, wherein: the air blowers are fixedly arranged on the imprinting station in a bilateral symmetry mode, and the placing station is fixedly arranged on the right side face of the right side boss of the device box body.