KR20230106009A - Concrescence apparatus in system for manufacturing of insulating glass - Google Patents

Abstract

The present invention comprises: a main body unit which has a support plate which supports a first glass and a second glass which are transferred in a state of being inclined at a predetermined angle to prevent overturning, and a conveyor which is arranged at the lower portion of the support plate to horizontally transfer the first glass and the second glass; and a bonding transfer unit which is moved in a back-and-forth direction with respect to the support plate of the main body unit, and bonds the first glass and the second glass which are transferred. The bonding transfer unit has a bonding plate of which each corner portion is coupled to the main body unit by means of a plurality of ball screws, and which is moved in a back-and-forth direction by means of the screw coupling according to the forward and reverse rotation of the ball screw. The bonding plate comprises: a main plate which is moved in a back-and-forth direction in a parallel state; and a sub-plate which is formed by an object by the separating line in a diagonal direction at one corner side of the main plate, and is coupled to be hinge-rotated. Therefore, reliability of the product may be prevented from deteriorating.

Description

Concrescence apparatus in system for manufacturing of insulating glass}

The present invention relates to an apparatus for bonding double-glazed glass, and more particularly, in a manufacturing system for manufacturing medium-sized or larger double-glazed glass in an in-line manner having a relatively large horizontal and vertical size, the glass different from each other with a gap therebetween. It relates to a bonding device of a double-glazed glass manufacturing system for bonding them together.

Recently, despite the relatively high price, the use of double-glazed glass is gradually increasing due to the advancement of living environment and the development of manufacturing technology according to economic improvement.

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

Double-glazed glass is a combination of two or more sheets of glass with a predetermined distance between them. Compared to single-glazed glass, it not only minimizes the loss of indoor energy, but also the surface temperature of the inner glass decreases relatively less despite the decrease in external temperature. The dew formation phenomenon is suppressed. In addition, since the soundproofing performance is excellent, transmission of noise between indoors and outdoors can be effectively blocked.

Conventional double-glazed glass is configured to include a first glass facing the inside of the building, a second glass forming the outer wall of the building, and a gap bar that separates the first glass and the second glass by a predetermined distance to maintain a constant space.

Inter-bars are generally made of aluminum so that they can firmly support the spaced glasses.

However, the inter-bar made of aluminum material has a high thermal conductivity, so the insulation effect is significantly reduced, and thus the view is greatly hindered by condensation caused by the temperature difference between the inner and outer surfaces of the glass. there was

In order to solve this problem, a bar using a synthetic resin has been proposed, and Korean Patent Registration No. 1021851 has been disclosed as a prior art related thereto.

For the inter-bar made of synthetic resin, a TPS material that can improve the insulation effect, and a thermoplastic spacer containing a moisture absorbent such as polyisobutylene are suitable.

In the case of double-glazed glass interposed with TPS gap bars, when a glass with TPS gap bars applied on one side is bonded to another glass, the TPS gap bars are wider than the pre-designed gap between the double-glazed glass. will spread

That is, when the gap between the inner surfaces of the first glass and the second glass forming the double-glazed glass is 12 mm, the width of the TPS gap is applied at approximately 13 to 14 mm, because the first glass and the second glass This is to take into account that when the glass is bonded with the TPS inter-rod in between, the width of the unsolidified TPS inter-rod shrinks due to the pressure caused by the bonding.

However, as described above, when the first glass and the second glass are bonded with the TPS inter-bar in between, and the TPS inter-bar is compressed in a state where the unsolidified TPS inter-bar is solidified, the production of double-glazed glass is completed. , the air present in the space between the first glass and the second glass and the solidified TPS is also compressed.

Therefore, the compressed air inherent in the space between the first glass and the second glass and the TPS gap between the double-glazed glass continues to expand the first glass and the second glass, and the gap between the TPS gap There is a problem that the reliability of the product is lowered according to the loss of confidentiality, such as a possibility of occurrence.

In particular, when airtightness is lost due to the expansion of compressed air, the gas contained in the space between the gaps of the TPS also leaks to the outside, resulting in a decrease in functionality such as soundproofing, windproofing, and heat insulation, which also lowers the reliability of the product. there was.

Korean Patent Registration No. 10-0758498 (2007.09.06.)

The present invention has been devised in view of the above-mentioned problems, and the technical problem to be solved by the present invention is, in a double-glazed glass manufacturing system that manufactures double-glazed glass in an in-line manner, a TPS inter-bonding is applied to one side. Manufacture of double-glazed glass to prevent the existence of compressed air in the inner space of the double-glazed glass by allowing the air existing in the space inside the TPS interbon to be discharged to the outside when one glass and the other glass are bonded together. It is to provide a bonding device for the system.

In other words, when one glass and another glass are bonded with the TPS gap between them, a part of the air inside the TPS gap is discharged to the outside, so that one glass and the other glass are bonded together. After bonding while compressing the PS gap, it prevents the expansion of one glass and the other glass by ensuring that no compressed air exists in the space between one glass and the other glass and the TPS gap. It is an object of the present invention to provide a bonding device of a double-glazed glass manufacturing system capable of preventing product reliability from deteriorating due to loss of confidentiality.

The tasks of the present invention are not limited to the tasks mentioned above, and other tasks not mentioned will be clearly understood by those skilled in the art from the following description.

In the bonding device of the double-glazed glass manufacturing system according to an embodiment of the present invention for solving the above problems, the first glass on which the TPS inter-bonding is not applied on one side and the second glass on which the TPS inter-bonding is applied on one side are bonded. In a bonding device made of double-glazed glass, a support plate for supporting the first glass and the second glass in an inclined state by a predetermined angle so that the transferred first glass and the second glass are not overturned, and disposed on the lower side of the support plate, the first glass and A main body portion in which a conveyor for horizontally conveying the second glass is installed; A coalescing and conveying unit that moves forward and backward with respect to the support plate of the main body and bonds the first glass and the second glass to be transported, wherein each corner of the coalescing and conveying unit is connected to the main body by means of a plurality of ball screws. and a bonding plate that is coupled to the part and moved forward and backward by screwing according to forward and reverse rotation of the ball screw, wherein the bonding plate includes a main plate that moves forward and backward in a parallel state, and a corner side of one side of the main plate. It can be formed as an object by a dividing line in a diagonal direction and composed of a sub-plate coupled rotatably with a hinge.

At this time, the sub plate is installed to be connected to an actuator that is operated forward and backward by a control signal, and can be rotated with respect to the main plate by a set angle according to the operation of the actuator.

In addition, suckers for adsorbing the first glass are installed on the front surfaces of the main plate and the sub plate, and the suckers installed on the sub plate are arranged and installed at a higher density than the suckers installed on the main plate. can

Meanwhile, in a state in which the sucker of the bonding plate adsorbs the first glass and the second glass is disposed on the support plate, when the bonding conveyor moves forward to bond the first glass and the second glass, the An actuator may be operated to pull the sub-plate for a set time and then restore it to its original state.

Other specific details of the invention are included in the detailed description and drawings.

According to the bonding device of the double-glazing manufacturing system according to the embodiment of the present invention, in the double-glazing manufacturing system for manufacturing double-glazing in an in-line manner, one glass coated with TPS inter-bonding on one side and the other glass When the glass is bonded, the air present in the space inside the TPS gap is discharged to the outside, thereby providing an effect that no compressed air exists in the space inside the bonded double-glazed glass.

That is, according to the bonding device of the double-glazed glass manufacturing system according to the embodiment of the present invention, when one glass and another glass are bonded with the TPS gap in between, some of the air present inside the TPS gap is discharged to the outside, so that compressed air does not exist in the space between one glass and the other glass and the TPS gap after one glass and the other glass are bonded while compressing the TPS gap. As a result, the expansion of one glass and the other glass is prevented, thereby preventing a decrease in reliability of a product due to loss of airtightness.

Effects according to the present invention are not limited by the contents exemplified above, and more various effects are included in the present specification.

1 is a block diagram showing an in-line configuration of a double-glazed manufacturing system according to an embodiment of the present invention.
2 is a configuration diagram showing an in-line configuration of a double-glazing manufacturing system according to an embodiment of the present invention.
3 is a perspective view of a bonding device provided in a double-glazing manufacturing system according to an embodiment of the present invention.
4 is a front view illustrating a front configuration of the bonding plate in FIG. 3;
5 to 8 are side views sequentially showing states in which double-glazed glass is bonded by the bonding device according to an embodiment of the present invention.

Advantages and features of the present invention, and methods for achieving them, will become clear with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and only the present embodiments make the disclosure of the present invention complete, and common knowledge in the art to which the present invention belongs It is provided to fully inform the holder of the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numbers designate like elements throughout the specification.

Thus, in some embodiments, well-known processing steps, well-known structures, and well-known techniques have not been described in detail in order to avoid obscuring the interpretation of the present invention.

Terms used in this specification are for describing embodiments and are not intended to limit the present invention. In this specification, singular forms also include plural forms unless specifically stated otherwise in a phrase. The terms "comprises" and/or "comprising" as used in the specification do not preclude the presence or addition of one or more other components, steps and/or operations other than those mentioned. use as And "and/or" includes each and every combination of one or more of the recited items.

In addition, the embodiments described in this specification will be described with reference to perspective views, cross-sectional views, side views and/or schematic views, which are ideal exemplary views of the present invention. Accordingly, the shape of the illustrative drawings may be modified due to manufacturing techniques and/or tolerances. Therefore, embodiments of the present invention are not limited to the specific shapes shown, but also include changes in shapes generated according to manufacturing processes. In addition, in each drawing shown in the embodiment of the present invention, each component may be shown somewhat enlarged or reduced in consideration of convenience of explanation.

Hereinafter, a bonding device of a double-glazed manufacturing system according to an embodiment of the present invention will be described in detail based on the accompanying drawings.

1 is a block diagram showing an in-line configuration of a double-glazed manufacturing system according to an embodiment of the present invention, and FIG. 2 is a block diagram showing an in-line configuration of a double-glazed manufacturing system according to an embodiment of the present invention.

As shown in FIGS. 1 and 2, the double-glazed glass manufacturing system to which the bonding device 60 according to the embodiment of the present invention is applied has a set thickness of glass 3, 2 capable of forming outer or inner glass. It may be made of a configuration including a glass supply unit 10 so that they are supplied by a set sequence.

Here, the glass supply unit 10 may be supplied in a state in which the glasses 3 and 2 are cut to a set size.

In addition, the double-glazed glass manufacturing system includes a washing and drying unit 20 for washing and drying the glasses sequentially supplied from the glass supply unit 10, at least one transport unit 30, and TPS on one side of the transported glass. A TPS interstitial coating unit 40 for applying interstitial strips, one glass without TPS interstitial coating (hereinafter, referred to as a first glass) and another glass with TPS interstitial coating applied to one side (hereinafter referred to as a first glass) , It may be made of a configuration further comprising a bonding portion 60 (hereinafter referred to as a bonding device) for bonding the second glass).

In addition, the double-glazed glass manufacturing system includes an aligning unit 70 that receives the double-glazed glass that has been bonded and rotates it at a set angle, and a sealing unit 80 that applies a sealing material to the edge of the double-glazed glass supplied from the aligning unit 70. It may be made of a configuration further comprising.

The washing and drying unit 20 performs a function of spraying washing water on the glasses sequentially supplied from the glass supply unit 10 to wash them and then drying them by hot air.

In this way, the glass washed and dried on the surface by the washing and drying unit 20 is transferred to the TPS interstitial coating unit 40 by the transfer unit 30.

At this time, a conveyor belt is installed below the frame of the transport unit 30 to transport the glass, and a plurality of main outlets for blowing air to separate the transported glass from the frame may be formed on the conveyor belt.

In addition, a plurality of auxiliary outlets may be formed in the frame of the conveying unit 30 to blow air to separate the conveyed glass from the frame.

The TPS interstitial coating unit 40 bypasses the first glass, that is, the first glass 3, among the transferred glasses, and transfers it to the inspection unit 50 and the bonding device 60, and transports it later. It can perform the function of coating the TPS inter-bar 4 on one surface of the glass, that is, the second glass 2, and its operational relationship will be described in detail later.

The inspection unit 50 performs a function of visually inspecting whether or not there are foreign substances on the front and rear surfaces of the glass 3 and 2 to be transported, or inspecting by taking pictures of the camera.

In particular, in the case of the second glass 2 that is transported with the TPS inter-bar 4 applied, the presence or absence of foreign substances, such as TPS residues on one side of the glass during the coating process of the TPS inter-bar 4. It will perform the function of checking .

As described above, the bonding device 60 is different from each other, that is, the first glass 3 on which the TPS spacing is not applied on one side, and the TPS spacing between the TPS spacing application unit 40 on one side of the TPS spacing ( 4) performs a function of bonding the second glass 2 to which the coating is applied, and the configuration and operation of the bonding device 60 will be described later in detail.

The aligning unit 70 may perform a function of receiving the double-glazed glass bonded by the bonding device 60 and aligning it at an angle of about 2-3 degrees with respect to the vertical.

In the case of the above-described glass supply unit 10, washing and drying unit 20, transfer unit 30, TPS interstitial coating unit 40, inspection unit 50, and bonding device 60, the glasses are placed in an in-line manner. When being transferred, the transfer is performed in an inclined state of about 10 degrees relative to the vertical so that overturning does not occur during the transfer process.

Therefore, even in the case of the double-glazed glass bonded by the cementing device 60, the transport is performed in an inclined state of about 10 degrees. Since it is difficult to apply the double-glazed glass that is bonded and transported in the bonding device 60, it is preferable to align the double-glazed glass at an angle close to vertical. will perform

In this way, the double-glazed glass aligned at an angle of about 2-3 degrees with respect to the vertical by the aligning unit 70 is supplied to the sealing unit 80 and the sealing material is applied to the edge of the double-glazed glass. manufacturing is complete.

Here, as shown in FIG. 2, the sealing part 80 is divided into a first sealing part 82 and a second sealing part 84 at left and right intervals, and the double-glazed glass is divided into the first sealing part 82 and the second 2 Sealing material is applied to the edge while reciprocating the sealing part 84 in advance.

3 is a perspective view of a bonding device provided in a double-glazed glass manufacturing system according to an embodiment of the present invention, FIG. 4 is a front view showing the front configuration of the bonding plate in FIG. 3, and FIGS. 5 to 8 are of the present invention. It is a side view sequentially showing a state in which double-glazed glass is bonded by the bonding device according to the embodiment.

As shown in FIGS. 3 to 8 , the bonding device 60 according to the embodiment of the present invention includes a support plate 610 that supports the glass 3 and 2 being transported in an inclined state at a predetermined angle so that the glass 3 and 2 are not overturned. ), and a body portion provided with a conveyor (reference numeral not given) disposed on the lower side of the support plate 610 to transport the glasses 3 and 2 in a horizontal direction by a control signal, and a support plate 610 of the body portion ), but moves forward and backward in the facing direction, and includes a bonding transfer unit (reference numeral not given) in which a bonding plate 620 is installed for bonding the glass 3 and 2 to be transferred. .

Each corner of the coalescing and conveying unit is coupled to the main body by a plurality of ball screws (reference numerals are not given), so that the coalescing and conveying unit can move forward and backward with respect to the main body by a control signal.

At this time, the bonding device 60 according to the embodiment of the present invention bonds medium-sized or larger glasses 3 and 2 with relatively large horizontal and vertical lengths, and accordingly, the area of the bonding plate 620 is also relatively large. As a large one is provided, it is preferable that the guide rail 640 is installed at the lower part of the coherent transport unit, and the coherent transport unit moves forward and backward at equal intervals with respect to the support plate 610 along the guide rail 640. do.

For reference, each ball screw is installed to pass through the upper side of the support plate 610 of the main body and the lower side of the conveyor, so that the glass (3) horizontally moved by the conveyor while one side is supported by the support plate 610 ,2) may be configured not to cause interference.

Here, drive motors for normal and reverse rotation of each ball screw are installed inside the main body, and ends of each ball screw may be rotatably installed with respect to a fixed plate (not shown) by a bearing member.

In addition, the cohesive transport unit is disposed between the support plate 610 of the main body and the fixed plate of the cohesive transport unit, and forward and backward in conjunction with the fixed plate by screw coupling according to the forward and reverse rotation of the ball screws, and the fixed plate and the fixed plate It may be configured to further include a bonding plate 620 disposed spaced apart from each other and having a plurality of suckers 624 and 628 installed on the front surface.

Here, the bonding plate 620 is formed as an object by a main plate 622 that moves forward and backward in a parallel state in conjunction with the fixed plate, and a diagonal separation line at one corner of the main plate 622, and is a hinge ( 630) may be composed of a sub plate 626 rotatably coupled by a hinge.

Accordingly, the sub plate 626 may be formed in a substantially triangular shape as it is separately formed by a diagonal dividing line at one corner of the main plate 622 .

In addition, the bonding device 60 according to an embodiment of the present invention may be installed to be separately connected to the sub plate 626 and further include an actuator 650 that moves forward and backward by a control signal.

At this time, suckers 624 and 628 are formed on the front surfaces of the main plate 622 and the sub plate 626, respectively, and the sucker 628 formed on the sub plate 626 is the sucker 624 formed on the main plate 622. ) It is preferable that the density is higher by being arranged more densely compared to ).

The operating relationship of the bonding device 60, which can be configured as described above, will be described as follows.

The glass supply unit 10, the washing and drying unit 20, the transfer unit 30, the TPS inter-seal application unit 40, and the inspection unit 50 are sequentially passed through, but the TPS inter-seal application unit 40 When the first glass 3 to which the gap bar is not applied is supplied to the bonding device 60, the first glass 3 is in a stopped state while being supported by the support plate 620 of the bonding device 60. will achieve

In this state, the control unit applies a rotation signal to each of the ball screws, and the coupling plate 620 constituting the coupling transfer unit moves forward by the rotation of the ball screws.

When the bonding plate 620 advances and the suckers 624 and 628 formed on the front surface of the bonding plate 620 adsorb the first glass 3, the control unit applies a reverse rotation signal to each ball screw, and the ball screw As shown in FIG. 5 , the cohesion plate 620 constituting the cohesive transfer part is moved backward by reverse rotation of the cohesive plate 620 .

In this way, after adsorbing the first glass 3, the bonding plate 620 is spaced apart from the support plate 620, and the TPS interstitial bar 4 is applied by the TPS interstitial bar coating unit 40. When the two glasses 2 are supplied to the bonding device 60, the second glass 2 is in a stopped state while being supported by the support plate 610 of the bonding device 60.

In this state, the control unit applies a rotation signal to each of the ball screws, and the rotation of the ball screws causes the bonding plate 620 constituting the bonding transfer unit to move forward as shown in FIG. The glass 3 and the second glass 2 are bonded together.

At this time, the bonding plate 620 adsorbing the first glass 3 moves forward and the second glass G2 supported by the support plate 610, that is, the first glass plate 4 coated with the TPS interstitial bar 4 on one side thereof. At the time of bonding with the second glass 3, the actuator 650 is controlled to pull the sub plate 626 backward while moving backward.

Therefore, the sub plate 626 is rotated at an angle with respect to the main plate 622 based on the separation line, as shown in FIG. 6 with the hinge such as the hinge 630 as the starting point. When (3) and the second glass (2) are bonded, the air existing in the space between the first glass (3), the second glass (2) and the TPS inter-bong (4) is installed by the sub plate (626). It exits through the affected area.

That is, since the first glass 3 is provided with a medium or larger glass having a horizontal and vertical size equal to or greater than a set size, as mentioned above, it has a predetermined luminance, so that even if it is bent by a certain angle while holding a portion of the end, it is not damaged. Alternatively, since no breakage occurs, even if the sub plate 626 is rotated obliquely with respect to the main plate 622, the corner of the first glass 3 adsorbed to the sucker 628 of the sub plate 626 is slightly bent. No damage or breakage will occur.

After that, as shown in FIGS. 7 and 8, when the actuator 650 is extended by the control signal and bonding is performed so that the first glass 3 and the second glass 2 are parallel, the first glass ( 3) and the second glass 2 and the TPS gap bar 4, there is no compressed air, so that the expansion of the first glass 3 and the second glass 2 is prevented and loss of airtightness Product reliability deterioration due to occurrence can be prevented.

At this time, as described above, since the sucker 628 formed on the sub plate 626 has a higher density than the sucker 624 formed on the main plate 622, the first glass is pulled and bent at a certain angle. One corner of (3) can be bent more stably.

Those skilled in the art to which the present invention pertains will understand that the present invention can be embodied in other specific forms without changing its technical spirit or essential features. Therefore, the embodiments described above should be understood as illustrative in all respects and not limiting. The scope of the present invention is indicated by the following claims rather than the detailed description above, and all changes or modifications derived from the meaning and scope of the claims and equivalent concepts should be construed as being included in the scope of the present invention. do.

2: 2nd glass 3: 1st glass
60: bonding device 610: support plate
620: cementation plate 622: main plate
624,628: sucker 626: sub plate
630: hinge 650: actuator

Claims (4)

In the bonding device for manufacturing double-glazed glass by bonding a first glass without a TPS inter-bar on one side and a second glass with a TPS inter-bar applied on one side,
A main body installed with a support plate for supporting the first glass and the second glass to be conveyed in an inclined state at a predetermined angle so that the first glass and the second glass are not overturned, and a conveyor disposed on the lower side of the support plate to horizontally transfer the first glass and the second glass wealth;
And moving forward and backward with respect to the support plate of the main body, including a bonding and conveying unit for bonding the first glass and the second glass to be transferred,
The coalescing and conveying unit,
Each corner portion includes a coupling plate coupled to the main body by a plurality of ball screws and moved forward and backward by screw coupling according to forward and reverse rotation of the ball screws,
The bonding plate,
A main plate that moves forward and backward in a parallel state;
The cementing device of the double-glazed glass manufacturing system, characterized in that composed of a sub-plate formed as an object by a dividing line in a diagonal direction at one edge of the main plate and coupled rotatably by a hinge.
According to claim 1,
The sub-plate is installed to be connected to an actuator that is operated forward and backward by a control signal, and rotates with respect to the main plate by a set angle according to the operation of the actuator.
According to claim 1,
Suckers for adsorbing the first glass are installed on front surfaces of the main plate and the sub plate,
The bonding device of the double-glazed glass manufacturing system, characterized in that the sucker installed on the sub plate is arranged and installed at a higher density than the sucker installed on the main plate.
According to claim 2,
In a state in which the sucker of the bonding plate adsorbs the first glass and the second glass is disposed on the support plate, when the bonding conveyor moves forward to bond the first glass and the second glass,
The bonding device of the double-glazed glass manufacturing system, characterized in that the actuator is operated to pull the sub-plate for a set time and then restore it to its original state.

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