KR102240153B1 - Dual pressing device for manufacturing double-layered glass - Google Patents

Abstract

Disclosed is a dual multilayer glass manufacturing apparatus. A loading unit having a first transfer unit formed of a plurality of rollers at a lower portion to seat and move the glass plate, and having a plurality of rollers formed on the first support plate supporting the glass plate; A washing unit comprising a brush member for washing the glass plate transferred from the loading unit, a washing water supply unit for injecting washing water, and a drying unit for drying by injecting dry air; A second transfer unit comprising a plurality of rollers is formed at the lower part so as to move the glass plate seated, and a plurality of rollers are formed on the second support plate supporting the glass plate to visually inspect the damage of the glass plate; A supply unit formed with a front glass support and a rear glass support so that the first and second glass plates that have been inspected are simultaneously transferred from the front side and the rear side; The first and second glass plates are composed of a fixing plate in which the first and second glass plates are adsorbed and spaced apart from the front and rear surfaces, and a front operation plate and a rear operation plate which are formed to be spaced apart from the front and rear surfaces of the fixing plate to be operated forward and backward to pressurize. A dual pressing unit having first and second slots each formed by pressing each of the first and second glass plates after the attached multilayer glass is disposed, respectively; And a lead-out portion formed with a front glass support and a rear glass support so that the first and second multilayer glass assemblies completed in the first and second slots are simultaneously transferred from the front side and the rear side, respectively.

Description

Dual pressing device for manufacturing double-layered glass

Disclosed is a dual pressing apparatus for manufacturing a multilayer glass, and more particularly, to a dual pressing apparatus for manufacturing a multilayer glass capable of pressing a plurality of multilayer glass composed of a glass plate attached to both sides of an interlayer.

Unless otherwise indicated herein, the content described in this section is not prior art to the claims of this application, and inclusion in this section is not admitted to be prior art.

Although it is relatively expensive, the use of multi-layered glass is gradually increasing due to the advanced living environment and the development of manufacturing technology due to the improvement of economic power.

In other words, the demand for double-layered glass is gradually increasing in accordance with the desire of consumers to pursue a more comfortable living environment out of noise, from large buildings to small shops and private houses.

Multi-layered glass is a combination of two or more sheets of glass at a predetermined interval. Compared with single-layered glass, it not only minimizes the loss of indoor energy, but also reduces the surface temperature of the inner glass relatively less despite the decrease in the external temperature. Condensation of dew is suppressed.

In addition, due to its excellent soundproofing performance, it is possible to effectively block noise transmission between indoors and outdoors.

Multi-layered glass is formed by bonding intersealed plate glass and untreated plate glass.

Meanwhile, in the prior art, a glass plate is attached to both sides of a single rod and a gas is injected to complete a multilayer glass assembly of a finished product.Since only one can be manufactured, there is a limitation in mass production, so there is a disadvantage of low manufacturing efficiency.
Existing pressing equipment uses a pair of pressing plates to produce one set of multi-layered glass or two sets of small multi-layered glass less than 1.2m in length in a series manner, and two pressing units (also known as double pressing equipment) are used. Therefore, it is divided into the process of producing 2 sets of large sized glass or 4 sets of small sized glass in series.
This requires a wide installation space and has to be controlled sequentially, so there is a limit to the production of mass or high-speed products.

Korean Utility Model Publication No. 1995-03262

The present invention was conceived to solve the problems of the prior art, and it is an object of the present invention to provide a dual multilayer glass manufacturing apparatus capable of remarkably improving production capacity by simultaneously pressing and molding two multilayer glass assemblies at the same time.

An object of the embodiment is to manufacture a multilayer glass with glass plates attached to both sides of a gap bar, and a fixed plate having an air nozzle for inhaling or injecting high-pressure air so that the first and second glass plates are adsorbed or spaced apart from each other on the front and rear sides; A front operating plate formed on the front surface of the fixing plate, being in close contact with or spaced apart from the front surface of the fixing plate while being operated back and forth, and having an air nozzle configured to suck or inject high-pressure air so that the first glass plate is adsorbed or separated; A first driving unit that exerts a forward and backward operation power of the front operating plate; A rear operation plate formed on the rear surface of the fixed plate, and having an air nozzle for suctioning or spraying high-pressure air so that the second glass plate is adsorbed or separated from the fixed plate while being operated back and forth; A second driving unit that exerts a forward and backward operation power of the rear operation plate; A power source for supplying or inhaling high-pressure air to the air nozzle formed on the fixing plate, the front operation plate, and the rear operation plate; 2 It can be achieved by a dual multilayer glass manufacturing apparatus in which a first slot is formed between the fixing plate and the front operation plate so that the glass plates are respectively pressed and formed, and a second slot is respectively formed between the fixing plate and the rear operation plate.

According to the disclosed embodiment, it is possible to produce two finished products at the same time a multilayer glass composed of glass plates attached to both sides of a cross bar, so that manufacturing efficiency can be remarkably improved.
In addition, by arranging two pairs of pressing plates in parallel using three operating plates, the working space is maximized, and since individual operation is possible, smooth and high-speed production is possible without any problem in sequential control. In particular, the effect can be maximized when gas injection of large-sized multi-layered glass is performed.

1 is a perspective view of a dual pressing device for manufacturing a multilayer glass according to the present invention,
2 is a side view of a dual pressing device for manufacturing a multilayer glass according to the present invention,
3 is a view showing a state in which the first and second glass plates are respectively entered into the fixed plate and the rear operation plate;
4 is a view showing a state in which the front operation plate and the rear operation plate are advanced and moved close to the fixed plate, and are pressed against the first and second glass plates;
5 is a view showing a state in which the first and second glass plates are moved by adsorption as the front operation plate and the rear operation plate are spaced apart from the fixed plate;
6 is a view showing a state in which the interlayers are attached to the fixing plate and the rear operation plate, respectively,
7 is a view showing a step of injecting gas in a state in which the front operation plate and the rear operation plate are advanced and moved close to the fixed plate to be in close proximity to the double-layered glass with the interlayer attached thereto
8 is a view showing a state in which the front operation plate and the rear operation plate are advanced and moved close to the fixed plate to be pressed in close contact with the double-layered glass to which the interlayer is attached;
9 is a view showing a state in which the front operation plate and the rear operation plate are retracted and spaced apart from the fixed plate to form a finished product.

Hereinafter, preferred embodiments will be described in detail based on the accompanying drawings.

The embodiments to be described below are intended to be described in detail enough to allow those of ordinary skill in the art to carry out the invention easily, thereby limiting the technical spirit and scope of the present invention. I don't mean it.

In addition, the size or shape of the constituent elements shown in the drawings may be exaggerated for clarity and convenience of description, and terms specially defined in consideration of the configuration and operation of the present invention vary according to the intention or custom of users and operators. It should be noted that, and definitions for these terms should be made based on the contents throughout the present specification.

In the accompanying drawings, FIG. 1 is a perspective view of a dual pressing apparatus for manufacturing a multilayer glass according to the present invention, FIG. 2 is a side view of a dual pressing apparatus for manufacturing a multilayer glass according to the present invention, and FIG. Fig. 4 is a view showing a state in which the front operation plate and the rear operation plate are moved forward and close to the fixed plate, and are pressed against the first and second glass plates, and Fig. 5 is a view showing a state respectively entered into the rear operation plate. The operation plate is spaced apart from the fixed plate and the position of the first and second glass plates is moved by adsorption. FIG. 6 is a view showing a state in which the interlayer is attached to the fixed plate and the rear operation plate respectively, and FIG. 7 is A view showing the step of injecting gas while the front and rear operation plates are advanced and moved close to the fixed plate, and the gas is injected in a state close to the double-layered glass with the interlayer attached.FIG. 8 is the front operation plate and the rear operation plate move forward and move closer to the fixed plate. Figure 9 is a view showing a state in which the interlayer is in close contact with the double-layered glass to which the interlayer is attached and pressurized.

1 to 9, the dual pressing apparatus 500 for manufacturing a multilayer glass according to the present invention,

A fixing plate 520 having an air nozzle for sucking or injecting high-pressure air so that the first and second glass plates G1 and G2 are respectively adsorbed or spaced apart from the front and rear surfaces;

It is formed on the front surface of the fixing plate 520, is in close contact or spaced apart from the front surface of the fixing plate 520 while being operated back and forth, and an air nozzle that sucks or injects high-pressure air so that the first glass plate G1 is adsorbed or separated is formed. Plate 540;

A first driving unit 570 that exerts a forward and backward operation power of the front operation plate 540;

It is formed on the rear surface of the fixing plate 520, is in close contact with or spaced apart from the fixing plate 520 while being operated back and forth, and an air nozzle that sucks or injects high-pressure air so that the second glass plate G2 is adsorbed or spaced apart is formed. Plate 560;

A second driving unit 580 for exerting a forward and backward operation power of the rear operation plate 560;

And a power source (not shown) that exerts power to supply or inhale high-pressure air to the air nozzles formed on the fixing plate 520, the front operation plate 540, and the rear operation plate 560.

Between the fixing plate 520 and the front operating plate 540 so that the first and second glass plates G1 and G2 are formed by pressing after each of the double-layered glass G10 and G20 with interlayers attached to both sides of the fixing plate 520 is disposed. A first slot (S1) is formed, and a second slot (S2) is formed between the fixing plate 520 and the rear operation plate 560, respectively.

The fixing plate 520 has a rectangular plate shape, but an air pipe is formed therein so that air is sucked or discharged, and a plurality of air nozzles are formed at the front and rear surfaces, so that the first and second glass plates can be in close contact with the front and rear surfaces.

The first driving part 570 is formed on the base, is formed at right angles to the front upper and lower ends of the front operating plate 540 and has a threaded shaft 571 on the outer circumferential surface, and a pulley 572 coupled to the shaft 571 And a driving motor (not shown) for rotating the pulley 572, and upper and lower ends of the front operating plate 540 are screwed to the shaft 571.

Therefore, when the driving motor is driven to rotate the upper and lower pulleys 572 and the upper and lower shafts 571 rotate at the same time, the movement of the front operating plate 540 can be uniformly and stably performed back and forth by screw rotation. have.

The second driving part 580 is formed on the base and is formed perpendicularly to the front upper and lower ends of the rear operating plate 560 and has a threaded shaft 581 on the outer circumferential surface, and a pulley 582 coupled to the shaft 581 And a driving motor (not shown) that rotates the pulley 582, and upper and lower ends of the rear operation plate 560 are screwed to the shaft 581.

Therefore, when the driving motor is driven to rotate the upper and lower pulleys 582 and the upper and lower shafts 581 are rotated at the same time, the movement of the rear operation plate 560 can be uniformly and stably performed back and forth by screw rotation. have.

In the first and second slots (S1, S2), the first and second glass plates (G1, G2) are respectively inserted after the double-layered glass (G4) with an interlayer is disposed, respectively, and the front operation plate 540 and the rear operation plate 560 may be driven to perform a pressurization operation.

A first transfer unit 110 and a second transfer unit 110 are formed in the first and second slots S1 and S2, respectively.

That is, the first transfer unit 511 consisting of a conveyor belt that is supported by a plurality of rollers and rotated to move the first glass plate G1 vertically is a first between the fixing plate 520 and the front operating plate 540. It is formed under the slot S1.

A second transfer unit 512 consisting of a conveyor belt rotated by being supported by a plurality of rollers at the bottom to move the second glass plate G2 vertically is a second slot between the fixing plate 520 and the rear operation plate 560 ( It is formed in the lower part of S2).

Meanwhile, a gas injection unit (not shown) connected to the first and second slots S1 and S2 is included.

The gas injection part is placed in the multilayer glass (G41, G42) with the interlayer rod attached, and the multilayer glass (G41, G42) with the interlayer through a finely spaced gap just before the first and second glass plates (G1, G2) are adhered. Inject gas.

The power source includes a plurality of air nozzles formed on the front and rear surfaces of the fixing plate 520 and a vacuum pump connected to the air nozzle to generate an adsorption force, and may be temporarily fixed by adsorbing glass on the front and rear surfaces.

It includes a plurality of air nozzles formed on one side of the front operation plate 540 and the rear operation plate 560, and a vacuum pump connected to the air nozzle to generate an adsorption force, and is temporarily fixed by adsorbing glass on the front and rear surfaces. I can make it.

Hereinafter, the operation of the present invention will be described with reference to FIGS. 2 and 3 to 9.

2 and 3, the dual pressing unit 500,

The first glass plate G1 is adsorbed on the front surface of the fixed plate 520 and the second glass plate G2 is adsorbed on the rear operation plate 560.

A first slot (S1) and a second slot (S2) are formed by being spaced apart from the front operating plate 540 and the rear operating plate 560 at intervals of 70 mm based on the fixing plate 520 in the middle.

2 and 4,

The front operating plate 540 is moved (referred to as forward) toward the fixed plate 520 so as to be in close contact with the first glass plate G1.

The rear operation plate 560 is also moved (referred to as backward) toward the fixed plate 520 to be in close contact with the second glass plate G2.

2 and 5,

The front operating plate 540 moves backward and is spaced apart from the fixed plate 520, and the first glass plate G1 is adsorbed to the front operating plate 540.

The rear operation plate 560 is spaced apart from the fixing plate 520, and the second glass plate G2 is adsorbed on the rear surface of the fixing plate 520.

2 and 6,

The first and second multi-layered glass G41 and G42 with aluminum interlayer F attached to the first and second slots S1 and S2 respectively enter.

The first and second double-layered glass (G41, G42) to which the interlayer is attached are moved to the front and rear surfaces of the fixing plate 520, respectively, but are floated at fine intervals by air sprayed from the air nozzles on the front and rear surfaces of the fixing plate 520. Is moved.

After the movement is completed in an appropriate position, the first and second multilayer glasses G41 and G42 to which the interlayers are attached are closely fixed to the front and rear surfaces of the fixing plate 520, respectively.

2 and 7,

The front operation plate 540 advances and approaches the fixing plate 520, and the rear operation plate 560 moves and approaches the fixing plate 520.

A partition (not shown) is in close contact with the side to close the first slot S1 and the second slot S2 to be sealed.

After that, gas is injected at the side position so that the gas is filled in the first and second multilayer glasses G41 and G42 to which the interlayer is attached.

2 and 8,

The front operating plate 540 is further advanced so that the first glass plate G1 and the first multilayer glass G41 are in close contact, and then pressurized to seal.

The rear operation plate 560 is further moved so that the second glass plate G2 and the second multilayer glass G42 are in close contact with each other, and pressurized and sealed.

2 and 9,

The front operation plate 540 is moved to be spaced apart from the fixing plate 520, and the rear operation plate 560 is spaced apart from the fixing plate 520.

The completed multilayer glass assemblies G10 and G20 are left in the first slot S1 and the second slot S2, respectively.

Thereafter, the completed multilayer glass assemblies G10 and G20 are transferred to the outside and transferred to a drawer (not shown).

The multilayer glass assemblies G10 and G20 transferred to the withdrawal part are sealed by an auto-sealing robot (not shown).

Although it has been described in connection with the preferred embodiment, it will be readily recognized by those skilled in the art that various modifications and variations are possible without departing from the gist and scope of the invention, and all such changes and modifications fall within the scope of the appended claims. Is self-explanatory.

520: fixed plate 540: front operating plate
560: rear operation plate 570: first driving unit
580: second driving part S1: first slot
S2: second slot 511: first

Claims (6)

It is to manufacture a multi-layered glass with glass plates attached to both sides of the liver bar,
A fixing plate having an air nozzle configured to suck or inject high-pressure air so that the first and second glass plates are adsorbed or spaced apart from each other on the front and rear surfaces;
A front operating plate formed on the front surface of the fixing plate, being in close contact with or spaced apart from the front surface of the fixing plate while being operated back and forth, and having an air nozzle for sucking or spraying high-pressure air so that the first glass plate is adsorbed or separated from each other;
A first driving unit that exerts a forward and backward operation power of the front operating plate;
A rear operation plate formed on the rear surface of the fixing plate, and having an air nozzle that sucks or injects high-pressure air so that the second glass plate is adsorbed or spaced apart from the fixed plate while being operated back and forth;
A second driving unit that exerts a forward and backward operation power of the rear operation plate;
Consists of; a power source that exerts power to supply or inhale high-pressure air to the air nozzle formed on the fixed plate, the front operation plate, and the rear operation plate,
A first slot is formed between the fixing plate and the front operation plate so that the first glass plate is inserted after the double-layered glass with interlayers attached to both sides of the fixing plate is disposed, and the second glass plate is inserted between the fixing plate and the rear operation plate. Dual multilayer glass manufacturing apparatus, characterized in that the two slots are formed. The method of claim 1,
The first driving unit includes a shaft formed on a base, formed at right angles to the upper and lower ends of the front operating plate, and threaded on an outer circumferential surface, and a pulley coupled to the shaft and a driving motor rotating the pulley, and Dual multilayer glass manufacturing apparatus, characterized in that the upper and lower ends of the front operating plate are screwed together. The method of claim 1,
The second driving unit includes a shaft formed on the base and perpendicular to the upper and lower ends of the rear operation plate and having a threaded thread on an outer circumferential surface thereof, and a pulley coupled to the shaft and a drive motor rotating the pulley, and the shaft Dual multilayer glass manufacturing apparatus, characterized in that the upper and lower ends of the rear operating plate are screwed together. The method of claim 1,
The front operation plate is a dual multi-layer glass manufacturing apparatus, characterized in that the suction force is formed in the air nozzle when separated after being in contact with the fixed plate so that the first glass plate is adsorbed. The method of claim 1,
A dual multilayer glass manufacturing apparatus, characterized in that after the second glass plate attached to the rear operation plate is in contact with the fixed plate, it is adsorbed to the rear surface of the fixed plate by the suction force of the air nozzle. The method of claim 1,
The front operation plate is close to the fixed plate, and after the rear operation plate is close to the fixed plate, and includes a partition formed on the side to block the first slot and the second slot,
The dual multilayer glass manufacturing apparatus, characterized in that the gas is filled after being sealed with the partition.

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