KR20190013324A - Dual dual layer glass manufacturing equipment - Google Patents

Abstract

Disclosed is a dual multi-layer glass manufacturing apparatus comprising: a loading unit having a first transport unit having a plurality of rollers on a lower portion thereof to move a glass plate by placing the glass plate thereon, and a plurality of rollers formed on a first support plate to support a glass plate; a washing unit including a brush member to wash a glass plate transported from the loading unit, a washing water supply unit to spray washing water, and a drying unit to spray dry air to dry a glass plate; an inspection unit having a second transport unit having a plurality of rollers on a lower portion thereof to move a glass plate by placing the glass plate thereon, and a plurality of rollers formed on a second support plate to support a glass plate to inspect damage to a glass plate with naked eyes; a supply unit having a front and a rear glass support unit to simultaneously transport a first and a second glass plate which have undergone inspection on a front side and a rear side; a dual pressing unit including a fixing plate wherein the first and the second glass plate are separated and sucked onto a front and a rear surface thereof, and a front and a rear operating plate separated and formed on the front and the rear surface of the fixing plate to press by being moved forwards and backwards, and having a first and a second slot on which the first and the second glass plate are pressed and formed after multi-layer glass with a rod attached thereto is arranged on both sides of the fixing plate; and a withdrawal unit formed on the front and the rear glass support unit to simultaneously transport a first and a second multi-layer glass assembly finished on the first and the second slot on the front and the rear side.

Description

Technical Field [0001] The present invention relates to dual dual layer glass manufacturing equipment,

The present invention relates to a dual-layered glass manufacturing apparatus, and more particularly, to a dual-layered glass manufacturing apparatus capable of simultaneously manufacturing two or more double-layered glass constituted by glass plates attached to both sides of a bar.

Unless otherwise indicated herein, the contents set forth in this section are not prior art to the claims of this application and are not to be construed as prior art to be included in this section.

In recent years, despite the relatively high price, the use of double-layered glass is gradually increasing due to the upgrading of the living environment due to the improvement of the economic power and the development of the manufacturing technology.

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, away from noise, as well as large buildings as well as small shops and private homes.

The two-layered glass is bonded between two or more glasses with a predetermined gap, so that the loss of room energy is minimized as compared with the single-layer glass, and the surface temperature of the inner glass is relatively lowered Dew condensation phenomenon is suppressed.

Also, since the soundproofing performance is excellent, noise transmission between indoor and outdoor can be effectively blocked.

The double-layered glass is formed by joining the glazed plate glass and the untreated plate glass.

On the other hand, according to the related art, a glass plate is attached to both sides of a single bar, and gas is injected to produce a double-layered glass of the finished product. However, since only one double-layered glass assembly can be manufactured, manufacturing efficiency is low.

Korean Utility Model Publication No. 1995-03262

It is an object of the present invention to provide a dual-layer glass manufacturing apparatus capable of simultaneously producing two finished products of a double-layered glass composed of glass plates attached to both sides of a short bar.

An object of the present invention is to provide an apparatus and a method for manufacturing a glass plate, comprising: a stacking unit in which a first conveying unit including a plurality of rollers is formed at a lower portion to receive and move a 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 spraying the washing water, and a drying unit for spraying and drying the drying air; An inspection unit for forming a second transfer unit comprising a plurality of rollers at a lower portion to receive and move the glass plate and a plurality of rollers formed at the second support plate for supporting the glass plate to visually inspect the breakage of the glass plate; A supply part having a front glass supporting part and a rear glass supporting part so that the first and second glass plates tested are simultaneously transferred from the front side and the rear side; The first and second glass plates are sandwiched between the front and rear surfaces of the fixing plate. The front and rear operation plates are spaced apart from the front and rear surfaces of the fixing plate, A dual pressing part in which first and second slots are formed in which first and second glass plates are respectively press-formed after the attached double-layered glass is disposed; And a lead-out portion having a front glass support portion and a rear glass support portion 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, have.

The supply unit includes a plurality of rollers for supporting and moving the first glass plate, the first and second glass plates being formed in a grid-like frame and having a third conveying unit formed of a plurality of main rollers formed at a lower portion of the frame, A support; A plurality of nozzles for discharging high-pressure air to float the second glass plate, and a second rear glass support unit having a fourth transfer unit formed of a plurality of main rollers at a lower portion thereof.

A frame having a lower end coupled to the second front glass support and a second rear glass support, A base on which a rail is formed on an upper surface of the frame so that the rail member of the frame is coupled and slid; And a gap adjusting unit configured by a pinion gear formed on the frame and a motor for rotating the pinion gear, and a rack gear formed on one side of the base in the longitudinal direction and having a pinion gear meshingly engaged therewith.

The dual pressing unit includes: a fixing plate having first and second moving units formed at front and rear sides of the first and second glass plates so that the first and second glass plates are respectively introduced into the front and rear sides; A front operating plate formed on one side of the fixing plate and moving back and forth to constitute a first slot; A first driving unit which exerts forward / backward operation power of the front operating plate; A rear operating plate formed on the other side of the fixing plate and configured to move forward and backward to constitute a second slot; A second driving unit which exerts forward / backward operation power of the rear operating plate; And adsorption means for generating an adsorption force for adsorbing the glass plate on the front and back surfaces of the front operation plate, the rear operation plate, and the fixing plate.

The drawer includes a front glass support portion having a plurality of rollers for supporting and moving the first multilayer glass and formed by a frame having a lattice structure and a fifth conveying unit including a plurality of rollers formed at a lower portion thereof, A plurality of nozzles for discharging high-pressure air so as to float the glass, and a rear glass support unit having a sixth transfer unit formed by a plurality of rollers at a lower portion thereof.

According to the disclosed embodiment, it is possible to simultaneously produce two finished products at the same time of the double-layered glass composed of glass plates attached to both sides of the barrel, thereby remarkably improving the manufacturing efficiency.

BRIEF DESCRIPTION OF DRAWINGS FIG. 1A is a plan view of a dual-
1B is a front view showing a dual-layered glass-making apparatus according to the present invention.
FIG. 2 is a plan view of a 'washing section' in the dual-layered glass making apparatus according to the present invention,
3 is a perspective view of an 'inspection unit' in an apparatus for manufacturing a dual-layered glass according to the present invention,
4 is a front perspective view of the 'supply part' in the dual-layered glass manufacturing apparatus according to the present invention,
FIG. 5 is a rear perspective view of a 'supply part' in the dual-layered glass manufacturing apparatus according to the present invention,
FIG. 6 is a side view of a 'supply part' in an apparatus for manufacturing a dual-layered glass according to the present invention,
FIG. 7 is a rear view of a part of a 'supply part' in an apparatus for manufacturing a dual-layered glass according to the present invention,
8 is a perspective view of a 'dual pressing part' in the dual-layered glass manufacturing apparatus according to the present invention,
9 is a side view of the 'dual pressing part' in the dual-layered glass manufacturing apparatus according to the present invention,
10 is a view showing a state where the first and second glass plates are respectively inserted into the fixing plate and the rear operating plate,
11 is a view showing a state in which the front operation plate and the rear operation plate are advanced and moved close to the fixing plate and pressed onto the first and second glass plates,
12 is a view illustrating a state in which the first and second glass plates are moved by suction while the front operation plate and the rear operation plate are separated from the fixing plate,
13 is a view showing a state in which the third and fourth glass plates with the baffle attached thereto are respectively inserted into the fixing plate and the rear operating plate,
14 is a view showing a step of injecting a gas in a state in which the front operating plate and the rear operating plate are advanced and moved close to the fixing plate so as to be in proximity to the third and fourth glass plates to which the baffle is attached,
15 is a view showing a state in which the front operation plate and the rear operation plate move forward and are moved close to the fixing plate and are pressed tightly to the third and fourth glass plates to which the baffle is attached,
16 is a view showing a state in which a front operation plate and a rear operation plate are retracted and separated from a fixing plate to form an article.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention as claimed. It does not mean anything.

In addition, the sizes and shapes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation, and the terms defined specifically in consideration of the configuration and operation of the present invention may vary depending on the intention or custom of the user, operator It should be noted that the definitions of these terms should be made on the basis of the contents throughout this specification.

As shown in FIGS. 1 to 3, the dual-layered glass manufacturing apparatus according to the present invention comprises:

The loading unit 100, the cleaning unit 200, the inspection unit 300, the supply unit 400, the dual pressing unit 500, and the drawing unit 600 are sequentially connected.

The loading unit 100

A first transfer unit 110 formed of a plurality of rollers is formed at a lower portion to vertically move the glass plate G and includes a first support plate 120 for supporting the glass plate G in a standing state, A plurality of rollers 122 are formed on the front surface of the support plate 120 so that a glass plate G can be rolled.

The glass plate G of the loading unit 100 is transferred to the cleaning unit 200.

Referring to FIG. 2,

A brush member 210 for cleaning the glass plate G transferred from the loading unit 100, a washing water supply unit 220 for spraying the washing water, and a drying unit 230 for spraying and drying dry air.

The brush member 210 includes two circular brushes 212 to be circumscribed and includes a driving motor 214 for rotating each of the circular brushes 212 so that the two circular brushes 212 pass through the glass plate G The front and rear surfaces are cleaned.

In addition, high-pressure washing water is sprayed from the washing water supplying unit 220 to wash the water.

The brush member 210 is constituted by a pair of two circular brushes 212, and a pair of the circular brushes 212 are continuously arranged in three pairs.

Two rollers 240 are disposed outside the brush member 210 in the middle of the brush member 210 and one of the two rollers 240 receives the rotational force from the motor 242 and rotates to transfer the glass plate G.

Referring to FIG. 3,

A plurality of rollers for supporting and moving the first glass plate G are formed on the front side and are formed in a grid-like frame, and a first transfer unit 311 formed of a plurality of main rollers formed at the lower part of the frame is formed A first front glass supporting part 310;

A first rear glass support 320 having a plurality of nozzles for discharging high-pressure air to float the second glass plate G and a second transfer unit 322 formed of a plurality of rollers at the bottom;

.

The first front glass supporting part 310 is formed such that a plurality of rectangular pipes are assembled in a lattice shape so that a large number of spaces are formed and the rear can be seen.

Therefore, it is possible to visually grasp foreign materials existing on the glass plate G passing through the first front side glass supporting part 310 and the glass plate G passing through the first rear side glass supporting part 320 or damage.

Here, the first rear glass support part 320 is formed in a plate shape having a thickness, a plurality of air nozzles are formed on the front side, and an air compressor (not shown) for supplying air to one side is connected.

Accordingly, the high-pressure air is injected through the air nozzle, so that the glass plate that is seated on the first rear glass support part 320 is floated at a predetermined interval and then moved by the driving of the second transfer unit 322.

3, a first positioning part 340 is formed in the first front glass supporting part 310 of the inspection part 300 to set the position of the interleaving F in order to arrange the interleaving F on the glass plate .

The interleave position setting unit 340

A cylinder 341 formed horizontally below the first front glass supporting part 310;

A cylinder rod 342 coupled to the cylinder 341 and operated back and forth;

A link 343 having one end hinged to the cylinder rod 342;

A guide rod 344 coupled to the other end of the link 343 and rotatably formed at both sides of a side of the first front glass support 310;

A fixing member 346 having a plurality of guide grooves 344 horizontally formed therein and having a stopper 347 which is in close contact with an end of the glass plate;

.

Therefore, when the cylinder rod 342 is pulled out, the guide rod body 344 is rotated by 90 degrees in association with the rotation of the link 343.

The fixing member 346 connected to the rotated guide member 344 is horizontally arranged with respect to the first front glass supporting part 310 and the stopper 347 is formed vertically so that the end of the glass plate G is fixed to the stopper 347, .

The stopper 347 is brought into close contact with the edge of the glass plate so as to adhere to the edge of the glass plate.

Therefore, the gap F can be vertically arranged in parallel with the end portion of the glass plate, so that defects can be prevented.

4 to 7, the supply unit 400 includes

The second front glass supporting part 410 and the second rear glass supporting part 420 are formed so that the first and second glass plates G1 and G2 after inspection are simultaneously transferred from the front side and the rear side.

The second front side glass supporting part 410 is formed in a lattice shape so that the rear side can be seen with the naked eye.

The second rear glass supporting part 420 is formed in a plate shape, and a plurality of air nozzles are formed on the front side thereof. An air compressor is connected to one side of the second rear glass supporting part 420 to blow air at high pressure through an air nozzle, .

The second front glass supporting part 410

A plurality of rollers 412 for supporting and moving the first glass plate G are formed on the front side and are formed as a lattice type frame and a third conveying unit 413 composed of a plurality of main rollers formed at a lower portion of the frame Respectively.

The second rear-side glass support 420

A plurality of nozzles for discharging high-pressure air to float the second glass plate G2, and a fourth transfer unit 424 including a plurality of main rollers.

Meanwhile, the second front glass supporting part 410 and the second rear glass supporting part 420 include a gap adjusting part 440 so that they can move at an interval of about 250 to 300 mm at the same time.

That is, in order to sequentially accommodate the glass plates introduced one by one in the inspection unit 300 from the second front side glass supporting part 410 and the rear side second rear side glass supporting part 420, the second front side glass supporting part 410 and the rear side And the second rear glass supporting part 420 must move forward and backward while alternately moving.

The interval adjusting unit 440

A frame 442 having a lower end coupled to the second front glass support 410 and a second rear glass support 420 and having a rail member 441 formed thereunder;

A base 444 having a rail 443 formed at an upper portion thereof and mounted on the ground so that the rail member 441 of the frame 442 is engaged and slid;

A pinion gear 445 formed on the frame 442 and a motor 446 for rotating the pinion gear 445. The pinion gear 445 is formed on one side of the base 444 in the longitudinal direction, And a rack gear 447 coupled thereto.

Therefore, when the motor 446 is driven by the signal of the control unit, the pinion gear 445 is driven to move along the rack gear 447, so that the frame 442 can be selectively moved forward and backward to selectively receive the glass plates G1 and G2 So that the position interval can be adjusted.

Referring to Figures 8 and 9,

The dual pressing portion 500

A front plate 540 spaced apart from the front and rear surfaces of the fixing plate 520 to be pressed forward and backward and to be pressed against the front and rear surfaces of the fixing plate 520, And a plate 560.

The first and second slots S1 and S2 are spaced apart from the front plate 540 and the rear plate 560 at both sides of the fixing plate 520, respectively.

The dual pressing part 500 includes:

A fixing plate 520 having first and second moving units 511 and 512 formed on the front and rear sides so that the first and second glass plates G are respectively introduced into front and rear sides;

A front actuation plate 540 formed at one side of the fixing plate 520 and configured to move forward and backward to constitute a first slot S1;

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

A rear actuating plate 560 formed on the other side of the fixing plate 520 and configured to move forward and backward to form a second slot S2;

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

Suction means (not shown) for generating suction force to cause the front plate 540, the rear plate 560, and the fixing plate 520 to adsorb the glass plate;

.

The first and second glass plates G1 and G2 are inserted into the first and second slots S1 and S2 after the double glazed glass plates G4 having the baffle are respectively disposed and the front operation plate 540 and the rear operation plate 540, (560) is driven and a pressing operation can be performed.

And a gas injection unit (not shown) connected to the first and second slots S1 and S2.

The gas injection unit injects gas into the double glazed glass G4 to which the cap is attached and the minute glass glass G4 to which the cap is attached through the gaps spaced slightly before the first and second glass plates G1 and G2 are bonded .

The suction means includes an air nozzle formed on the front and rear surfaces of the fixing plate, and a vacuum pump connected to the air nozzle to generate an attraction force, and the glass can be temporarily fixed on the front and rear surfaces.

The lead-out portion 600

The third front glass supporting part 610 and the third rear glass supporting part 610 are disposed such that the first and second glass-reinforced glass assemblies G10 and G20 completed in the first and second slots S1 and S2 are simultaneously transferred from the front side and the rear side, 620 are formed.

Since the drawing unit 600 is similar to the feeding unit 400, a duplicate description thereof will be omitted.

The operation of the present invention will be described with reference to FIGS. 10 to 16. FIG.

Referring to FIG. 10, the dual-pressing unit 500 includes:

The first glass plate G is adsorbed on the front surface of the fixing plate 520 and the second glass plate G is adsorbed on the rear operation plate 560.

The first operation plate 540 and the second operation plate 560 are spaced apart from each other by a distance of 70 mm from the center of the fixing plate 520 to form a first slot S1 and a second slot S2.

11,

The front operation plate 540 moves toward the fixing plate 520 (advances) and is brought into close contact with the first glass plate G. [

The rear operation plate 560 is also moved toward the fixing plate 520 (referred to as "backward movement") to closely contact the second glass plate G.

12,

The front operation plate 540 is retracted to be spaced from the fixing plate 520 and the first glass plate G is sucked to the front operation plate 540.

The rear operation plate 560 is spaced apart from the fixing plate 520 and the second glass plate G is sucked to the rear surface of the fixing plate 520. [

13,

A second glass plate (first and second glass gums G41 and G42 with a barb) each having an aluminum interstice F assembled into the first slot S1 and the second slot S2, respectively.

The first and second multilayer glass plates G41 and G42 with the diaphragm are moved to the front and back sides of the fixing plate 520 and are moved at a small interval by the air injected from the air nozzles of the front and rear faces of the fixing plate 520 It is moved in a floating state.

After the movement is completed at the proper position, the first and second multilayer glasses G41 and G42 with the intermediate bar F are tightly fixed to the front and back surfaces of the fixing plate 520, respectively.

14,

The front operating plate 540 advances to come close to the fixing plate 520 and the rear operating plate 560 moves to approach the fixing plate 520. [

A partition (not shown) is closely attached to the side so as to close the first slot S1 and the second slot S2.

Thereafter, gas is injected at the side position so that the gas is filled in the barrel.

15,

The front operation plate 540 is further advanced so that the first glass plate G and the first multilayer glass G4 are brought into close contact with each other,

The rear operating plate 560 further moves so that the second glass plate G and the second double-layer glass G4 are brought into close contact with each other so as to be pressed and sealed.

16,

The front operating plate 540 moves and is spaced from the fixing plate 520 and the rear operating plate 560 is spaced apart from the fixing plate 520. [

The completed two-layer glass assemblies G10 and G20 remain in the first slot S1 and the second slot S2, respectively.

The completed multi-layer glass assemblies (G10 and G20) are then transferred to the outside and transferred to the drawing unit 600.

Referring to FIG. 1, a sealing operation is performed by the autoclave robot 700, which is delivered to the lead-out portion 600.

It will be apparent to those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the invention, and all such changes and modifications are intended to be within the scope of the appended claims. It is self-evident.

100: loading part 120: first supporting plate
200: cleaning part 210: brush member
220: wash water supply unit 230: drying unit
300: Inspection section 310: First front glass supporting section
320: first rear glass support part 340:
341; Cylinder 342:
343: Link 344: Guide rod
346: fixing member 347; stopper
400; Feeder 410: Second front glass support
420: second rear glass supporting part 440:
442: frame 444: base
445: pinion gear 446: motor
447; Rack gear 500: Dual pressing part
520: Fixing plate 540: Front working plate
560: rear working plate 570: first driving part
580:

Claims (6)

A loading unit in which a first transfer unit including a plurality of rollers is formed at a lower portion to move the glass plate thereon, and a plurality of rollers are formed on a first support plate for 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 spraying the washing water, and a drying unit for spraying and drying the drying air;
An inspection unit for forming a second transfer unit comprising a plurality of rollers at a lower portion to receive and move the glass plate and a plurality of rollers formed at the second support plate for supporting the glass plate to visually inspect the breakage of the glass plate;
A supply part having a front glass supporting part and a rear glass supporting part so that the first and second glass plates tested are simultaneously transferred from the front side and the rear side;
The first and second glass plates are adsorbed and spaced from the front and rear surfaces. The front and rear operation plates are spaced apart from the front and rear surfaces of the fixing plate, A dual pressing part in which first and second slots are formed in which first and second glass plates are respectively press-formed after the attached double-layered glass is disposed;
A drawer having a front glass supporting part and a rear glass supporting part formed such 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;
And a second dual-layer glass manufacturing apparatus. The method according to claim 1,
Wherein the supply unit includes:
A second front glass supporting part formed with a plurality of rollers for supporting and moving the first glass plate and formed of a lattice type frame and having a third conveying unit formed of a plurality of main rollers formed at the lower part of the frame;
A plurality of nozzles for discharging high-pressure air to float the second glass plate, and a second rear glass support member
And a second dual-layer glass manufacturing apparatus. 3. The method of claim 2,
A frame having a lower end coupled to the second front glass support and a second rear glass support,
A base on which a rail is formed on an upper surface of the frame so that the rail member of the frame is coupled and slid;
An interval adjusting unit comprising a pinion gear formed on the frame and a motor for rotating the pinion gear, and a rack gear formed on one side of the base in a longitudinal direction and having a pinion gear meshingly engaged therewith;
And a second dual-layer glass manufacturing apparatus. The method according to claim 1,
The dual-
A fixing plate having first and second moving units formed on front and rear sides of the first and second glass plates so that the first and second glass plates respectively flow in front and rear;
A front operating plate formed on one side of the fixing plate and moving back and forth to constitute a first slot;
A first driving unit which exerts forward / backward operation power of the front operating plate;
A rear operating plate formed on the other side of the fixing plate and configured to move forward and backward to constitute a second slot;
A second driving unit which exerts forward / backward operation power of the rear operating plate;
Adsorption means for generating adsorption forces for adsorbing the glass plate on the front and back surfaces of the front operation plate, the rear operation plate, and the fixed plate;
And a second dual-layer glass manufacturing apparatus. The method according to claim 1,
The draw-
A front glass supporting part formed with a plurality of rollers for supporting and moving the first multilayer glass and formed by a frame having a lattice structure and a fifth conveying unit including a plurality of rollers formed at a lower part; And a second glass support part having a sixth conveying unit formed by a plurality of rollers at a lower part thereof for conveying the first and second multilayer glass. Device. The method according to claim 1,
The washing unit
A brush member for washing the glass plate transferred from the loading section, a washing water supply section for spraying washing water, and a drying section for spraying and drying dry air,
Wherein the brush member includes a plurality of circular brushes circumscribed and a drive motor for rotating each of the circular brushes so that the front and rear surfaces are cleaned while the glass plates are passed through the plurality of circular brushes.

Images