KR102240154B1 - Dual dual layer glass manufacturing equipment - Google Patents

Abstract

A glass plate multiple feeder is disclosed. The glass plate multi-supplying device according to an embodiment includes a plurality of rollers supporting and moving the first glass plate on the front side and formed in a lattice-shaped frame, and a third made of a plurality of main rollers formed under the frame. A front glass support portion having a transfer unit formed thereon; A plurality of nozzles for discharging high-pressure air to float the second glass plate are formed, and a rear glass support portion on which a fourth transfer unit consisting of a plurality of main rollers is formed is formed at a lower portion thereof.
According to this, it is possible to simultaneously transfer at least two or more of a glass plate or a glass plate with an interlayer to the pressure assembly unit, so that a plurality of multilayer glass assemblies can be produced at the same time, so that production efficiency can be significantly improved.

Description

Glass plate multiple supply device {Dual dual layer glass manufacturing equipment}

Disclosed herein relates to a glass plate multi-supplying device, and more particularly, to a glass plate multi-supplying device capable of simultaneously supplying a plurality of glass plates to produce a multi-layered glass formed by attaching an interlayer between two glass plates.

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.

In spite of being relatively expensive in recent years, 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 pieces of glass at a predetermined interval. Compared with single-layered glass, it not only minimizes the loss of indoor energy, but also the surface temperature of the inner glass does not decrease despite the decrease in the external temperature, resulting in condensation. The phenomenon is suppressed.

And it has excellent soundproofing performance, so it can effectively block the transmission of noise between indoors and outdoors.

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

Looking at the multilayer glass manufacturing process, a sheet of glass is transferred and supplied to a presser after the cleaning process and inspection process.

After that, in the inspection process, the glass plate with the thinner bar is supplied to a presser, and then gas is injected while compressing to complete the multilayer glass assembly.

Conventionally, since the operation is performed by supplying a glass plate one by one, there is a disadvantage in that the manufacturing efficiency of the multilayer glass assembly is low.

Korean Utility Model Publication No. 1995-03262

Disclosed is a glass plate multi-supplying device capable of simultaneously transferring at least two or more glass plates or glass plates with an interlayer attached to the pressurization assembly to produce multiple multi-layered glass assemblies at the same time, so that production efficiency can be remarkably improved. It has its purpose.

The object of the embodiment is to be applied to a multilayer glass manufacturing apparatus, in which a plurality of rollers supporting and moving the first glass plate are formed on the front side and formed in a grid-shaped frame, and a plurality of main rollers formed under the frame. A front glass support portion having a third transfer unit formed thereon; A plurality of nozzles for discharging high-pressure air to float the second glass plate are formed, and a rear glass support portion on which a fourth transfer unit consisting of a plurality of main rollers is formed is formed at a lower portion, wherein the first glass plate is disposed on the front glass support portion. In the seated state, it can be moved by roller driving, and by allowing the second glass plate to be moved by air floating and roller driving while the second glass plate is seated on the rear glass support, it is possible to move the two glass plates.

According to the disclosed embodiment, it is possible to simultaneously transfer at least two or more of a glass plate or a glass plate with an interlayer to the pressure assembly unit, thereby contributing to the simultaneous production of a plurality of multi-layered glass assemblies, so that production efficiency can be significantly improved. .

1 is a front perspective view showing a glass plate multiple supply device according to the present invention,
Figure 2 is a perspective view from above of a glass plate multi-supplying device according to the present invention,
Figure 3 is a rear perspective view showing a glass plate multiple supply device according to the present invention,
Figure 4 is a side view showing a glass plate multiple supply device according to the present invention,
Figure 5 is an enlarged side view of the main part of the glass plate multi-supplying device according to the present invention,
6 is an enlarged rear perspective view of a glass plate multi-supplying device according to the present invention,
7 is an enlarged partial perspective view of the'interval control unit' of the glass plate multi-supplying device according to the present invention;
8 is a plan view showing a multilayer glass manufacturing apparatus to which the present invention is applied,
9 is a front view showing a multilayer glass manufacturing apparatus to which the present invention is applied.

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 front perspective view showing a multi-supplying device for glass plates according to the present invention, FIG. 2 is a perspective view from above of a multi-supplying device for glass plates according to the present invention, and FIG. 3 is a multi-supplying apparatus for glass plates according to the present invention. Shown a rear perspective view, Figure 4 is a side view showing a glass plate multi-supplying device according to the present invention, Figure 5 is an enlarged side view of the main part of the glass plate multi-supplying device according to the present invention, Figure 6 is an enlarged rear perspective view of the glass plate multi-supplying device according to the present invention 7 is an enlarged partial perspective view of the'interval control unit' of the glass plate multi-supplying device according to the present invention, FIG. 8 is a plan view showing a multilayer glass manufacturing apparatus to which the present invention is applied, and FIG. 9 is a multilayer glass to which the present invention is applied It is a front view showing the manufacturing apparatus.

Prior to describing the embodiment, a multilayer glass manufacturing apparatus to which the embodiment is applied will be described with reference to FIGS. 8 and 9.

The multilayer glass manufacturing apparatus is configured by sequentially connecting the loading unit 100, the washing unit 200, the inspection unit 300, the glass plate multiple supply unit 400, the pressure assembly unit 500, and the withdrawal unit 600.

The loading unit 100 is formed with a first transfer unit 110 consisting of a plurality of rollers at the bottom so as to move the glass plates G1 and G2 vertically, and supports the glass plates G1 and G2 in an erect state. One support plate 120 is included, and a plurality of rollers 122 are formed on the front surface of the first support plate 120 so as to roll and transport the glass plates G1 and G2.

Thereafter, the glass plates G1 and G2 in the loading unit 100 are transferred to the washing unit 200.

The washing unit 200 includes a brush member (not shown) for washing the glass plates G1 and G2 transferred from the loading unit 100, a washing water supply unit for injecting washing water, and a drying unit for drying by injecting dry air (not shown). Poetry).

The brush member has two circular brushes formed externally, and includes a driving motor that rotates each circular brush, so that the front and rear surfaces can be cleaned while the glass plate passes between the two circular brushes.

In addition, high-pressure washing water is sprayed from the washing water supply to perform water washing in parallel.

The brush member is composed of two circular brushes formed in a pair, but these circular brushes are arranged in three pairs in succession.

Two rollers are arranged circumferentially in each middle of the brush member, and one of the two rollers is rotated by receiving a rotational force from a motor to transfer the glass plate.

In the inspection unit 300, a plurality of rollers supporting and moving the first glass plate G1 are formed on the front side and formed in a grid-shaped frame, and a transfer unit consisting of a plurality of main rollers formed under the frame is formed. 1 glass transfer unit 301 and; A plurality of nozzles for discharging high-pressure air are formed to float the second glass plate G2, and a rear glass support part 302 is formed at a lower portion of the transfer unit made of a plurality of rollers.

Hereinafter, a multi-supply device for glass plates according to an embodiment will be described.

As shown in FIGS. 1 to 7, the glass plate multiple supply device 400 according to the present invention includes a front glass support so that the inspected first and second glass plates G1 and G2 are transferred simultaneously from the front side and the rear side. It is configured to include (410) and the rear glass support (420).

The front glass support 410 has a plurality of rollers 412 that support and move the first glass plate G1 on the front side, and are formed in a square shape by connecting the beam members in a grid shape.

A third transfer unit 413 consisting of a plurality of main rollers and a driving source for rotating any one of the plurality of main rollers is formed under the front glass support part 410 to support and move the first glass plate G1. do.

The driving source is mainly an electric motor.

The rear glass support part 420 is formed by forming a plate-shaped portion made of a hexahedron having a predetermined thickness, and a plurality of nozzles formed on the front surface of the plate-shaped portion to discharge high-pressure air to float the second glass plate G2. A fourth transfer unit 424 formed of a plurality of main rollers for moving the second glass plate G2 is formed and configured in the lower part of the upper part.

On the other hand, the lower end of the front glass support 410 and the rear glass support 420 are coupled, and a frame 442 having a rail member 441 formed thereon is provided.

In addition, a rail 443 is formed on the upper portion so that the rail member 441 of the frame 442 is coupled and slides, and a base 444 installed on the ground is included.

Meanwhile, a connection bar 5 is formed that connects the upper end of the front glass support 410 and the rear glass support 420 and is adjustable in length.

The connection bar 5 is a pipe 52 with threads formed on the inner circumferential surface and open at both ends, and is screwed to both ends of the pipe 52 and is fixed to the front glass support 410 or the rear glass support 420 It consists of first and second knuckle (51, 53).

Therefore, when the pipe 52 is rotated, the first and second knuckles 51 and 53 are moved in different directions to increase or decrease the length, and by adjusting the length of the connection bar 5, the front glass support 410 And it is possible to adjust the spaced apart distance of the rear glass support 420.

On the other hand, the frame 442 is moved back and forth to drive the first and second glass plates G1 and G2 to alternately transfer the first and second glass plates G1 and G2 to the pressure assembly 500 includes a gap adjustment unit 440.

The spacing control unit 440 is capable of simultaneously moving the front glass support 410 and the rear glass support 420 back and forth at about 250-300 mm intervals, so that it can be adjusted to coincide with the entry position of the glass plate of the pressure assembly 500 .

The spacing control unit 440, referring to FIGS. 6 and 7, includes a motor 446 formed in the center of the base 444; A gearbox 45 which is coupled to the shaft of the motor 446, a plurality of gears connected thereto, and having a main shaft 452 formed in both directions; A drive shaft 455 connected to the main shaft 452 by a coupler 453, formed in the longitudinal direction of the base 444 on both sides, and coupled to a bearing so as to be rotatable; A pinion gear 445 formed at the ends of both drive shafts 455, and a rack gear 447 formed at one side of the base 444 in a direction orthogonal to the drive shaft 455 to which the pinion gear 445 is tooth-coupled It consists of;

Therefore, when the motor 446 is driven, power is transmitted through the gearbox 45 to rotate the main shafts 452 on both sides.

Both main shafts 452 are rotated in the same direction.

The rotational power of the main shaft 452 is transmitted to the drive shaft 455 through the coupler 453 to rotate.

When the drive shaft 455 is rotated, the pinion gear 445 is rotated, and the pinion gear 445 is moved by rotating along the rack gear 447.

Accordingly, the frame 442 on which the drive shaft 455 is mounted moves along the rail 443, and the front glass support 410 and the rear glass support 420 mounted on the frame 442 can also be moved together. .

Meanwhile, as shown in FIG. 3, a supporter 7 that connects the rear one side of the rear glass support 420 and the base to exert a supporting force is further included.

The supporter 7 has a lower end hinged to the base 444 with an axial pin 74, and the upper end is hinged with an axial pin 74 to an upper or middle rear portion of the rear glass support 420, and the rear glass support 420 This is to make it possible to adjust the tilt of

The supporter 7 is coupled to a tube body 71 having an open end and a hollow, and a piston rod 72 at both ends of the tube body 71 to be protruding and protruding, and an axial pin 74 at the end of each piston rod 72 The ring 73 is formed so as to be coupled, and an elastic means such as hydraulic pressure or spring is formed inside the tube body 71 of the supporter 7.

When hydraulic pressure is filled in the tube body 71 of the supporter 7, the piston rod 72 is pulled out or pulled in according to an increase or decrease in the hydraulic pressure, so that the inclination angle of the rear glass support 420 can be adjusted.

As shown in FIG. 5, the rear glass support 420 has an air chamber 82 formed inside a lower portion of a plate-shaped portion having a predetermined thickness, and an air compressor 8 is mounted on the rear surface thereof. In addition, a plurality of air nozzles 83 are formed on the front surface of the plate so as to communicate with the air chamber 82.

Therefore, by spraying high-pressure air from the plurality of air nozzles 83, the second glass plate G2 may float and be spaced apart.

In addition, by forming the air nozzle 83 to be inclined toward the front, the second glass plate G2 is floated by the injected air pressure, and a driving force that pushes forward may be applied.

Therefore, the second glass plate G2 entering the rear glass support 420 can be moved forward by being raised at a certain interval by the high-pressure air injection of the air nozzle 83 and then moved forward, and the fourth transfer unit at the bottom. It is advanced by the drive of 424.

The operation of the present invention configured as described above will be described as follows.

The operator manipulates the control unit (not shown) to operate and adjusts the appropriate interval so that the glass plates G1 and G2 can be accurately supplied to the pressure assembly unit 500 must be performed.

Therefore, when the motor 446 is driven, power is transmitted through the gearbox 45 to rotate the main shafts 452 on both sides.

Both main shafts 452 are rotated in the same direction.

The rotational power of the main shaft 452 is transmitted to the drive shaft 455 through the coupler 453 to rotate.

When the drive shaft 455 is rotated, the pinion gear 445 is rotated, and the pinion gear 445 is moved by rotating along the rack gear 447.

Therefore, the frame 442 on which the drive shaft 455 is mounted moves along the rail 443, and the front glass support 410 and the rear glass support 420 mounted on the frame 442 can also be moved together. The position of the pressure assembly unit 500 can be accurately adjusted.

Thereafter, the first glass plate G1 may be transferred to the front glass support part 410, and the second glass plate G2 may be transferred to the rear glass support part 420.

The first glass plate G1 or the second glass plate G2 may be transferred at the same time or may be selectively controlled to be transferred at a time difference.

Through this transfer method, a plurality of glass plates can be continuously transferred in mass, so that the final assembly operation can be performed more quickly in the pressure assembly unit 500, which is a post-process.

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.

5: connecting bar 51,53: 1st, 2nd knuckle
7: supporter 45: gearbox
71: tube body 72: piston rod
73: ring 74: shaft pin
400: supply unit 410: front glass support
420: rear glass support 440: gap adjustment unit
442: frame 444: base
445: pinion gear 446: motor
447: rack gear

Claims (6)

In transferring a glass plate applied to a multilayer glass manufacturing apparatus,
A front glass support portion having a plurality of rollers supporting and moving the first glass plate on the front side, formed in a grid-shaped frame, and having a third transfer unit formed of a plurality of main rollers formed under the frame;
Includes; a plurality of nozzles for discharging high-pressure air to float the second glass plate, and a rear glass support portion on which a fourth transfer unit consisting of a plurality of main rollers is formed at a lower portion, and
A frame having a lower end portion of the front glass support portion and the rear glass support portion coupled to each other, and having a rail member formed at the lower portion thereof;
A base having a rail formed on the upper side and installed on the ground so that the rail member of the frame is coupled to slide;
A gap adjusting unit for moving the frame and driving it back and forth so that the first and second glass plates are alternately transferred to the pressure assembly unit;
Glass plate multi-supply device comprising a. The method of claim 1,
The spacing control unit
A motor formed in the center of the base;
A gearbox coupled to the shaft of the motor, a plurality of gears connected thereto, and having a main shaft formed in both directions;
A drive shaft connected to the main shaft by a coupler, formed in the longitudinal direction of the base on both sides, and coupled to a bearing to be rotatable;
Pinion gears formed at ends of the drive shafts on both sides,
A rack gear formed on one side of the base in a direction orthogonal to the drive shaft to which the pinion gear is toothly coupled;
Glass plate multi-supply device comprising a. The method of claim 1,
The rear glass support
A plate-shaped portion having a predetermined thickness,
An air chamber formed inside the plate-shaped portion and an air compressor formed in a rear surface of the plate-shaped portion,
A plurality of air nozzles are formed so as to communicate with the air chamber on the front surface of the plate top portion,
A glass plate multi-supplying device, characterized in that high-pressure air is injected from a plurality of air nozzles so that the second glass plate is floated and separated from each other. The method of claim 1,
It includes a connecting bar that connects the upper end of the front glass support and the rear glass support and is adjustable in length,
The connection bar is a glass plate multiplex, characterized in that it includes a pipe having threads formed on an inner circumferential surface and having both ends open, and first and second knuckles that are respectively screwed to both ends of the pipe and fixed to the front glass support or the rear glass support. Supply. The method of claim 1,
It includes a supporter for exerting a support by connecting the rear one side and the base of the rear glass support,
The supporter is a glass plate multi-supplying device, characterized in that the lower end is hinged to the base, the upper end is hinged to the rear upper or middle portion of the rear glass support part with an axial pin to adjust the inclination of the rear glass support. The method of claim 5,
The above supporter
A tube body with open ends and a hollow;
Piston rods coupled to protrude and protrude to both ends of the tubular body;
A ring formed at the end of the piston rod to which the shaft pin is coupled;
An elastic means formed inside the tube body;
Glass plate multi-supply device comprising a.

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