CN113493315B - Device and method for processing hollow glass - Google Patents
Device and method for processing hollow glass Download PDFInfo
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- CN113493315B CN113493315B CN202110876451.1A CN202110876451A CN113493315B CN 113493315 B CN113493315 B CN 113493315B CN 202110876451 A CN202110876451 A CN 202110876451A CN 113493315 B CN113493315 B CN 113493315B
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- C—CHEMISTRY; METALLURGY
- C03—GLASS; MINERAL OR SLAG WOOL
- C03C—CHEMICAL COMPOSITION OF GLASSES, GLAZES OR VITREOUS ENAMELS; SURFACE TREATMENT OF GLASS; SURFACE TREATMENT OF FIBRES OR FILAMENTS MADE FROM GLASS, MINERALS OR SLAGS; JOINING GLASS TO GLASS OR OTHER MATERIALS
- C03C27/00—Joining pieces of glass to pieces of other inorganic material; Joining glass to glass other than by fusing
- C03C27/06—Joining glass to glass by processes other than fusing
- C03C27/10—Joining glass to glass by processes other than fusing with the aid of adhesive specially adapted for that purpose
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Abstract
The invention discloses a device and a method for processing hollow glass, which comprises a lower supporting plate, an upper pressing plate, a first telescopic rod and a clamping mechanism, wherein the upper surface of the lower supporting plate is in a wave shape matched with the lower surface of the hollow glass, the lower surface of the upper pressing plate is in a wave shape matched with the upper surface of the hollow glass, the first telescopic rod is used for driving the upper pressing plate to lift, two movable clamping mechanisms are arranged on two sides of the hollow glass along the direction of a wave-shaped section, the clamping mechanisms are connected with a first clamping rod and a second clamping rod, the first clamping rod is in a wave-shaped rod, the second clamping rod comprises a plurality of movable joints and rotating shafts, the movable joints are in a cross shape, arc-shaped plates are arranged at the upper end and the lower end of each movable joint, the arc-shaped end surfaces of the two arc-shaped plates are positioned on the same cylindrical surface, the left end and the right end of each adjacent movable joint are rotatably connected through the rotating shafts, the directions of the wave-shaped sections are perpendicular to each other, and bulges facing the first clamping rods are arranged on the side surfaces of the movable joints. The invention can avoid the cracking of the glass at the wave crest and the wave trough in the pressing process of the wavy glass.
Description
Technical Field
The invention relates to the technical field of glass processing, in particular to a device and a method for processing hollow glass.
Background
The hollow glass is a novel building material which has good heat insulation and sound insulation, is beautiful and applicable and can reduce the self weight of buildings. The high-efficiency sound-insulating and heat-insulating glass is prepared by bonding two (or three) pieces of glass with an aluminum alloy frame containing a drying agent by using a high-strength high-airtightness composite bonding agent. In the step of adding the hollow glass, a support frame coated with an adhesive needs to be placed on the lower layer of glass, the adhesive needs to be higher than the surface of the support frame by a certain thickness, and then the upper layer of glass is pressed on the support frame, so that the support frame and the glass can be bonded together by the adhesive, for example, an energy-saving double-layer hollow glass door window with the publication number of CN 205224995U. The method is only suitable for plane glass, in the process of producing the wave-shaped glass, as the support frame needs to be coated with the binding agent with a certain thickness, when the upper layer of the wave-shaped glass is pressed on the support frame, the wave-shaped glass at the initial stage is not contacted with the support frame at the wave crest and the wave trough, only the glass surface between the wave crest and the wave trough is contacted with the support frame, after the binding agent is extruded by the glass surface between the wave crest and the wave trough, the glass at the wave crest and the wave trough is pressed and contacted with the support bars, and then the glass between the wave crest and the wave trough at the initial stage is stressed by outward expanding force, so that the glass at the wave crest and the wave trough is cracked when the upper layer of the wave-shaped glass is pressed downwards.
Disclosure of Invention
Aiming at the prior art, the invention provides a device and a method for processing hollow glass, which can avoid the cracking of the glass at wave crests and wave troughs in the pressing process of the wavy glass.
The technical scheme of the invention is realized as follows:
the utility model provides a cavity glass's processingequipment, includes bottom suspension fagging, top board, first telescopic link and fixture, the upper surface of bottom suspension fagging be with cavity glass lower surface complex wave, the lower surface of top suspension fagging be with cavity glass upper surface complex wave, first telescopic link is used for the drive the top suspension fagging goes up and down, is equipped with two activities in cavity glass both sides along the sectional direction of wave the fixture, fixture is used for the centre gripping to establish the support bar in cavity glass both sides, fixture and first supporting rod and second supporting rod, first supporting rod is the wave pole, the second supporting rod includes a plurality of freely movable joints and pivot, freely movable joint is "ten" font and both ends are equipped with the arc, two the arc terminal surface of arc is located same face of cylinder, and is adjacent freely movable joint's the left and right sides both ends are rotated through the pivot and are connected, the pivot is perpendicular with the sectional direction of wave, freely movable joint's side is equipped with the arch towards first supporting rod.
Further, the supporting strips comprise first supporting strips and second supporting strips, the first supporting strips and the second supporting strips are wavy and located between two pieces of glass of the hollow glass, and bonding agents are arranged between the first supporting strips and the second supporting strips.
Furthermore, the protrusion is provided with a spherical groove, a ball is arranged in the spherical groove, and the ball extends out of the surface of the protrusion.
Furthermore, the lower supporting plate is arranged on the base, a second telescopic rod is arranged on the base and connected with the first clamping rod, and the second telescopic rod drives the first clamping rod to move along the direction perpendicular to the wave-shaped section.
Further, the base is provided with a third telescopic rod, a sliding block is arranged at the movable end of the third telescopic rod, the sliding block slides along the direction perpendicular to the waveform section, and the sliding block is used for pushing the second clamping rod to move towards the first clamping rod.
Furthermore, the base is provided with a motor, an output shaft of the motor is parallel to the waveform section, the output shaft is provided with a magnet for attracting the second clamping rod, and the output shaft on the opposite side of the magnet is provided with a balancing weight.
A method for processing glass by a hollow glass processing device comprises the following steps:
s1, placing lower-layer wavy glass on a lower supporting table, placing two wavy supporting bars on each of two sides of the lower-layer wavy glass, reserving glue injection gaps between the two supporting bars, injecting a binder into the glue injection gaps, and keeping the upper surfaces of the binder and the upper surfaces of the supporting bars flat;
s2, the two support bars and the adhesive form a sealing element, a first clamping rod is placed on the outer side of the sealing element, a second clamping rod is placed on the inner side of the sealing element, and the upper pressing plate is lowered down to press the upper layer of wavy glass through a first telescopic rod;
s3, placing the upper layer of the wavy glass on the sealing element, and clamping the first clamping rod and the second clamping rod tightly, so that the sealant is forced to extrude and adhere to the upper layer of the wavy glass and the lower layer of the wavy glass.
Further, in the step S1, after the adhesive is injected into the adhesive injection gap, the adhesive above the support bar is scraped by using a scraper, so that the upper surface of the adhesive is flush with the upper surface of the support bar.
The invention has the beneficial effects that: and the adhesive between the two support bars is extruded by utilizing the clamping force of the first clamping rod and the second clamping rod and is pressed on the upper wavy glass and the lower wavy glass. The adhesive has certain fluidity, the second clamping rods cannot rotate along the vertical direction of the waveform cross section, the pressure intensity of the inner wall of the adhesive is balanced under the action of the two clamping rods, the extrusion intensity of the adhesive and the glass extruded from different positions is uniform, the extrusion force is dispersed on the surface of the waveform glass, and the cracking of the waveform wave crests and the wave troughs is avoided in the process of extruding and bonding the adhesive and the waveform glass. The clamping mechanism can move, so that the clamping mechanism can be conveniently placed between the two wavy glass. First supporting rod is the wave pole, can directly utilize first supporting rod to extrude the support bar from the outside. The arc end surfaces of the two arc plates are positioned on the same cylindrical surface, and when any position between the wave-shaped glass is contacted with the movable joint, the interval between the wave-shaped glass and the movable joint is equal to the diameter of the cylindrical surface. After the extrusion bonding is finished, the second clamping rod is easily pulled out from between the waved glass. The shape of second supporting rod self can be adjusted in wave form section direction by relative rotation, can not rotate relatively in wave form section's vertical direction to ensure that two supporting rods can the centre gripping support bar make the binder adhesion on glass, avoid glass to take place the fracture. Utilize the arch to promote the support bar and extrude the binder, avoid the binder to glue on the second supporting rod, the arch is located the central point of face of cylinder and puts, utilizes freely movable joint to fix a position protruding in the centre of bracing piece, avoids the bracing piece slope to lead to the binder to distribute inhomogeneously at extruded in-process.
Drawings
In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only preferred embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to these drawings without inventive exercise.
FIG. 1 is a front view of an apparatus for processing a hollow glass according to embodiment 1 of the present invention;
FIG. 2 is a side view of an apparatus for processing hollow glass according to example 1 of the present invention;
FIG. 3 is a top view of a lower support plate of the hollow glass processing apparatus according to embodiment 1 of the present invention;
FIG. 4 is a partial front view of a second clamping bar according to embodiment 1 of the present invention;
FIG. 5 is a top view of a lower support plate of the hollow glass processing apparatus according to embodiment 2 of the present invention;
in the figure, 1 lower supporting plate, 2 upper press plate, 3 first telescopic link, 4 fixture, 5 first supporting rods, 6 second supporting rods, 7 movable joints, 8 rotating shafts, 9 arc-shaped plates, 10 protrusions, 11 first supporting strips, 12 second supporting strips, 13 binders, 14 spherical grooves, 15 balls, 16 bases, 17 second telescopic links, 18 third telescopic links, 19 sliding blocks, 20 motors, 21 magnets and 22 balancing weights.
Detailed Description
In order to better understand the technical content of the invention, specific embodiments are provided below, and the invention is further described with reference to the accompanying drawings.
Example 1
Referring to fig. 1 to 4, a hollow glass processing device includes a lower support plate 1, an upper pressure plate 2, a first telescopic rod 3 and a clamping mechanism 4, wherein the upper surface of the lower support plate 1 is in a wave shape matched with the lower surface of the hollow glass, the lower surface of the upper pressure plate 2 is in a wave shape matched with the upper surface of the hollow glass, the first telescopic rod 3 is used for driving the upper pressure plate 2 to ascend and descend, two movable clamping mechanisms 4 are arranged on two sides of the hollow glass along the direction of a waveform section, the clamping mechanism 4 is used for clamping support bars arranged on two sides of the hollow glass, the clamping mechanism 4 is connected with a first clamping rod 5 and a second clamping rod 6, the first clamping rod 5 is in a wave shape, the second clamping rod 6 includes a plurality of movable joints 7 and a rotating shaft 8, the movable joints 7 are in a cross shape, arc-shaped plates 9 are arranged at the upper and lower ends of the movable joints 7, arc-shaped end surfaces of the two arc-shaped plates 9 are located on the same cylindrical surface, the left end and the right end of each adjacent movable joint 7 are rotatably connected through the rotating shaft 8, the direction of the waveform section is perpendicular to the cylindrical surface of the movable joint 7, and a protrusion 10 facing the first clamping rod 5 is arranged on the side surface of the movable joint 7.
The upper surface of the lower support plate 1 is in a wave shape matched with the lower surface of the hollow glass, the lower layer of wave-shaped glass is placed on the lower support plate 1, the wave-shaped glass is in contact with the upper surface of the lower support plate 1, and the lower layer of wave-shaped glass is supported by the lower support plate 1. Rubber layers can be arranged on the surfaces of the lower supporting plate 1 and the upper pressing plate 2, and the anti-skidding protection effect is achieved. And then two support bars are respectively arranged on the wave-shaped edges at the two sides of the wave-shaped glass, and the height of each support bar is less than or equal to the distance between the upper layer of glass-shaped glass and the lower layer of glass-shaped glass in the hollow glass. And (3) injecting the adhesive 13 between the two support bars by using an adhesive injector, wherein the injected adhesive 13 is level with the height of the upper surfaces of the support bars, and the adhesive 13 on the upper surfaces of the support bars at the high positions is scraped by using a scraper. Then, a first clamping rod of the clamping mechanism 4 is placed at the edge of the wavy glass, a second clamping rod 6 is placed on the inner side of the wavy glass, then the first telescopic rod 3 is controlled to ascend and descend, the upper layer of the wavy glass is placed on the supporting bars, gaps are reserved between the upper layer of the wavy glass and the supporting bars, or the upper layer of the wavy glass and the supporting bars are in contact with each other but are not extruded with each other, and positive pressure and friction force are not generated. The first clamping rod 5 and the second clamping rod 6 are clamped tightly, the binding agent 13 between the two supporting strips is extruded out by utilizing the clamping force of the first clamping rod 5 and the second clamping rod 6, and the binding agent is pressed on the upper wavy glass and the lower wavy glass. The adhesive 13 has certain fluidity, the second clamping rods 6 cannot rotate along the vertical direction of the waveform cross section, the pressure intensity of the inner wall of the adhesive 13 is balanced under the action of the two clamping rods, the extrusion pressure of the adhesive 13 and the glass extruded at different positions is uniform, the extrusion pressure is dispersed on the surface of the waveform glass, and the cracking of the waveform wave crest and the wave trough is avoided in the extrusion bonding process of the adhesive 13 and the waveform glass. The clamping mechanism 4 is movable, so that the clamping mechanism 4 can be conveniently placed between the two pieces of wavy glass. The first clamping rods 5 are wavy rods, and the supporting bars can be directly extruded from the outer sides by the aid of the first clamping rods 5. The second clamping rod 6 comprises a plurality of movable joints 7 and a rotating shaft 8, the movable joints 7 are in a cross shape, arc-shaped plates 9 are arranged at the upper ends and the lower ends of the movable joints 7, the arc-shaped end faces of the two arc-shaped plates 9 are located on the same cylindrical surface, and when any position between the wavy glass is in contact with the arc-shaped plates 9 at the two ends of the movable joints 7, the interval between the wavy glass and the arc-shaped plates is equal to the diameter of the cylindrical surface. After the press bonding is finished, the second clamping bar 6 is easily drawn out from between the waved glasses. It is also possible to position the distance between the two corrugated glasses with the second clamping bar 6. It is adjacent both ends are rotated through pivot 8 and are connected about freely movable joint 7, pivot 8 is perpendicular with the sectional direction of wave form, and second supporting rod 6 can relatively rotate in the sectional direction of wave form and adjust the shape of self, can not rotate relatively in the sectional vertical direction of wave form to ensure that two supporting rods can the centre gripping support bar make binder 13 adhesion on glass, avoid glass to take place the fracture. The side of freely movable joint 7 is equipped with orientation the arch 10 of first supporting rod 5, and arch 10 and support bar contact utilize arch 10 to promote the support bar and extrude binder 13, avoid binder 13 to glue on second supporting rod 6, and arch 10 is located the central point of face of cylinder and puts, utilizes freely movable joint 7 to fix a position arch 10 in the centre of bracing piece, avoids the bracing piece slope to lead to binder 13 to distribute inhomogeneously at extruded in-process. After the press bonding is finished, the second clamping rod 6 is pulled out from between the waved glasses.
Specifically, the support strip includes first support strip 11 and second support strip 12, first support strip 11 and second support strip 12 are the wave, and are located between two blocks of glass of cavity glass, be equipped with binder 13 between first support strip 11 and the second support strip 12. Two support bars are adopted for supporting, and the support bars are fixed between the two wavy glasses. And a glue injection gap is formed between the two support bars, a binder 13 is injected into the glue injection gap, and the two support bars are bonded and extruded by the clamping mechanism 4. After bonding, the supporting strip is left between the two waved glasses.
Specifically, the protrusion 10 is provided with a spherical groove 14, a ball 15 is arranged in the spherical groove 14, and the ball 15 extends out of the surface of the protrusion 10. When the second clamping rods 6 are drawn out or moved from the wavy glass, the friction force between the second clamping rods 6 and the supporting bars can be reduced.
Specifically, the lower supporting plate 1 is arranged on a base 16, a second telescopic rod 17 is arranged on the base 16, the second telescopic rod 17 is connected with the first clamping rod 5, and the second telescopic rod 17 drives the first clamping rod 5 to move along the direction perpendicular to the wave-shaped section. When the second telescopic rod 17 is extended, the first clamping rods 5 are pushed into the wavy glass from the side, and when the second telescopic rod 17 is shortened, the first clamping rods 5 are pulled out from the wavy glass. One end of the first telescopic rod 3 is fixed on the base 16, the motion track of the first clamping rod 5 is driven to be fixed when the first telescopic rod is extended and shortened, the first clamping rod 5 is fixed in the middle of the supporting bar by the aid of the first extension rod, the supporting bar is prevented from inclining, and accordingly the binder 13 is uniformly distributed. The width of the first clamping rod 5 is smaller than that of the supporting bar, so that the extruded adhesive 13 can be prevented from being stuck on the first clamping rod 5.
Specifically, the base 16 is provided with a third telescopic rod 18, a sliding block 19 is arranged at the movable end of the third telescopic rod 18, the sliding block 19 slides along a direction perpendicular to the waveform section, and the sliding block 19 is used for pushing the second clamping rod 6 to move towards the first clamping rod 5. After the second clamping rods 6 are placed between the wavy glass, the third telescopic rods 18 are used for pushing the sliding blocks 19 to move, and the sliding blocks 19 are used for pushing the supporting rods through the movement of the second clamping rods 6, so that the adhesive 13 is extruded. Utilize the both ends motion of third telescopic link 18 synchronous promotion second supporting rod 6, it is even when second supporting rod 6 and first centre gripping extrusion support bar, avoid the support bar slope for the distribution of binder 13 is even.
Example 2
Referring to fig. 5, the present embodiment is different from embodiment 1 in that the base 16 is provided with a motor 20, an output shaft of the motor 20 is parallel to the wave-shaped cross section, the output shaft is provided with a magnet 21 for attracting the second clamping rod 6, and the output shaft on the opposite side of the magnet 21 is provided with a weight 22. The motor 20 drives the magnet 21 to rotate when rotating, and the output shaft on the opposite side of the magnet 21 is provided with the balancing weight 22, so that the stress is balanced when the output shaft rotates, and the vibration is reduced. When the magnet 21 rotates, the magnet 21 is periodically close to the second clamping rod 6, the second clamping rod 6 is periodically attracted by the magnet 21, and the second clamping rod 6 generates pulse force for pressing the supporting bar to promote the adhesive 13 of the supporting bar to extrude.
The method for processing the glass by using the processing device of the hollow glass comprises the following steps:
s1, placing lower-layer wavy glass on a lower supporting table, placing two wavy supporting bars on each of two sides of the lower-layer wavy glass, reserving glue injection gaps between the two supporting bars, injecting a binder 13 into the glue injection gaps, and keeping the upper surfaces of the binder 13 level with the upper surfaces of the supporting bars;
s2, the two support bars and the adhesive 13 form a sealing element, a first clamping rod 5 is placed on the outer side of the sealing element, a second clamping rod 6 is placed on the inner side of the sealing element, and the upper pressing plate 2 is lowered down by using the first telescopic rod 3 to press the upper layer of wavy glass;
s3, placing the upper layer of the wavy glass on the sealing element, and clamping the first clamping rod 5 and the second clamping rod 6 tightly, so that the sealant is forced to extrude and adhere to the upper layer of the wavy glass and the lower layer of the wavy glass.
Specifically, in the step S1, after the adhesive 13 is injected into the glue injection gap, the adhesive 13 above the support bar is scraped by using a scraper, so that the upper surface of the adhesive 13 is flush with the upper surface of the support bar.
The upper surface of the lower support plate 1 is in a wave shape matched with the lower surface of the hollow glass, the lower layer of wave-shaped glass is placed on the lower support plate 1, the wave-shaped glass is in contact with the upper surface of the lower support plate 1, and the lower layer of wave-shaped glass is supported by the lower support plate 1. Rubber layers can be arranged on the surfaces of the lower supporting plate 1 and the upper pressing plate 2, and the anti-skid protection effect is achieved. And then two support bars are respectively arranged on the wave-shaped edges at the two sides of the wave-shaped glass, and the height of each support bar is equal to the distance between the upper layer of glass-shaped glass and the lower layer of glass-shaped glass in the hollow glass. And (3) injecting a binder 13 between the two support bars by using the glue injector, wherein the injected binder 13 is level to the height of the upper surfaces of the support bars, and the binder 13 on the upper surfaces of the support bars at the high positions is scraped by using a scraper. Then, a first clamping rod of the clamping mechanism 4 is placed at the edge of the wavy glass, a second clamping rod 6 is placed on the inner side of the wavy glass, then the first telescopic rod 3 is controlled to ascend and descend, the upper layer of the wavy glass is placed on the supporting bars, gaps are reserved between the upper layer of the wavy glass and the supporting bars, or the upper layer of the wavy glass and the supporting bars are in contact with each other but are not extruded with each other, and positive pressure and friction force are not generated. The first clamping rod 5 and the second clamping rod 6 are clamped tightly, the binding agent 13 between the two supporting strips is extruded out by utilizing the clamping force of the first clamping rod 5 and the second clamping rod 6, and the binding agent is pressed on the upper wavy glass and the lower wavy glass. The adhesive 13 has certain fluidity, the second clamping rods 6 cannot rotate along the vertical direction of the waveform cross section, the pressure intensity of the inner wall of the adhesive 13 is balanced under the action of the two clamping rods, the extrusion pressure of the adhesive 13 and the glass extruded at different positions is uniform, the extrusion pressure is dispersed on the surface of the waveform glass, and the cracking of the waveform wave crest and the wave trough is avoided in the extrusion bonding process of the adhesive 13 and the waveform glass. The clamping mechanism 4 is movable, so that the clamping mechanism 4 can be conveniently placed between the two pieces of wavy glass. The first clamping rods 5 are wavy rods, and the supporting bars can be directly extruded from the outer sides by the aid of the first clamping rods 5. The second clamping rod 6 comprises a plurality of movable joints 7 and a rotating shaft 8, the movable joints 7 are in a cross shape, arc-shaped plates 9 are arranged at the upper ends and the lower ends of the movable joints 7, the arc-shaped end faces of the two arc-shaped plates 9 are located on the same cylindrical surface, and when any position between the wavy glass is in contact with the movable joints 7, the interval between the wavy glass and the movable joints is equal to the diameter of the cylindrical surface. After the press bonding is finished, the second clamping bar 6 is easily drawn out from between the waved glasses. It is also possible to position the distance between the two corrugated glasses with the second clamping bar 6. It is adjacent both ends are rotated through pivot 8 and are connected about freely movable joint 7, pivot 8 is perpendicular with the sectional direction of wave form, and second supporting rod 6 can relatively rotate in the sectional direction of wave form and adjust the shape of self, can not rotate relatively in the sectional vertical direction of wave form to ensure that two supporting rods can the centre gripping support bar make binder 13 adhesion on glass, avoid glass to take place the fracture. The side of freely movable joint 7 is equipped with orientation the arch 10 of first supporting rod 5, and arch 10 and support bar contact utilize arch 10 to promote the support bar and extrude binder 13, avoid binder 13 to glue on second supporting rod 6, and arch 10 is located the central point of face of cylinder and puts, utilizes freely movable joint 7 to fix a position arch 10 in the centre of bracing piece, avoids the bracing piece slope to lead to binder 13 to distribute inhomogeneously at extruded in-process. After the press bonding is finished, the second clamping rod 6 is pulled out from between the waved glasses.
The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.
Claims (8)
1. The utility model provides a cavity glass's processingequipment, its characterized in that includes bottom suspension fagging, top board, first telescopic link and fixture, the upper surface of bottom suspension fagging is with cavity glass lower surface complex wave, the lower surface of top board is with cavity glass upper surface complex wave, first telescopic link is used for the drive the top board goes up and down, is equipped with two activities in cavity glass both sides along the sectional direction of wave the fixture, fixture is used for the centre gripping to establish the support bar in cavity glass both sides, fixture and first supporting rod and second supporting rod, first supporting rod is the wave pole, the second supporting rod includes a plurality of freely movable joints and pivot, freely movable joint is "ten" font and both ends are equipped with the arc, two the arc terminal surface of arc is located same face of cylinder, and is adjacent the both ends are rotated through the pivot about freely movable joint and is connected, the pivot is perpendicular with the sectional direction of wave, the side of freely movable joint is equipped with towards the arch of first supporting rod.
2. The hollow glass processing device according to claim 1, wherein the supporting strips comprise a first supporting strip and a second supporting strip, the first supporting strip and the second supporting strip are wavy and are located between two pieces of hollow glass, and an adhesive is arranged between the first supporting strip and the second supporting strip.
3. The apparatus for processing hollow glass according to claim 1, wherein the projection is provided with a spherical groove, and a ball is provided in the spherical groove and protrudes from a surface of the projection.
4. The device for processing hollow glass according to claim 1, wherein the lower support plate is disposed on a base, a second telescopic rod is disposed on the base, the second telescopic rod is connected to the first holding rod, and the second telescopic rod drives the first holding rod to move along a direction perpendicular to the wave-shaped cross section.
5. The hollow glass processing device as claimed in claim 4, wherein the base is provided with a third telescopic rod, a sliding block is provided at a movable end of the third telescopic rod, the sliding block slides along a direction perpendicular to the wave-shaped cross section, and the sliding block is used for pushing the second clamping rod to move towards the first clamping rod.
6. The hollow glass processing device as claimed in claim 4, wherein the base is provided with a motor, an output shaft of the motor is parallel to the wave-shaped cross section, the output shaft is provided with a magnet for attracting the second clamping rod, and the output shaft on the opposite side of the magnet is provided with a counter weight.
7. The method for processing glass by using the hollow glass processing device as claimed in claim 1, comprising the steps of:
s1, placing lower-layer wavy glass on a lower support table, placing two wavy support bars on each of two sides of the lower-layer wavy glass, reserving a glue injection gap between the two support bars, injecting a binder into the glue injection gap, and keeping the upper surfaces of the binder and the upper surfaces of the support bars flat;
s2, the two supporting bars and the bonding agent form a sealing element, a first clamping rod is placed on the outer side of the sealing element, a second clamping rod is placed on the inner side of the sealing element, and the upper pressing plate is lowered down by using a first telescopic rod to press the upper layer of wavy glass;
s3, placing the upper layer of the wavy glass on the sealing element, and clamping the first clamping rod and the second clamping rod tightly, so that the sealant is forced to extrude and adhere to the upper layer of the wavy glass and the lower layer of the wavy glass.
8. The method for processing glass according to claim 7, wherein in the step S1, after the adhesive is injected into the glue injection gap, the adhesive above the supporting strip is scraped by a scraper so that the upper surface of the adhesive is flush with the upper surface of the supporting strip.
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| CN202110876451.1A CN113493315B (en) | 2021-07-30 | 2021-07-30 | Device and method for processing hollow glass |
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| CN202110876451.1A CN113493315B (en) | 2021-07-30 | 2021-07-30 | Device and method for processing hollow glass |
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| CN113493315B true CN113493315B (en) | 2022-11-15 |
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| CN213377592U (en) * | 2020-07-28 | 2021-06-08 | 甘肃峪晨玻璃科技有限公司 | Aluminum frame glue spreader for hollow glass |
| CN213202848U (en) * | 2020-09-25 | 2021-05-14 | 福建恒顺玻璃有限公司 | Sealed glue filling device that glues of cavity glass |
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2021
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| WO1988009424A1 (en) * | 1987-05-29 | 1988-12-01 | Holger Larsson I Mora Ab | A clamping apparatus for manufacture of insulating glass |
| EP0437418A1 (en) * | 1990-01-11 | 1991-07-17 | Peter Lisec | Manufacturing apparatus for insulating glazing |
| WO2017114795A1 (en) * | 2015-12-29 | 2017-07-06 | Bystronic Lenhardt Gmbh | Method for forming a closed frame-shaped spacer for an insulating glass pane |
| WO2018034573A1 (en) * | 2016-08-15 | 2018-02-22 | Stuart Dundonald Reid | Insulated glazing unit |
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