CN208897410U - A kind of synchronous transfer device of concave surface positioning and convex surface of 3D bend glass - Google Patents

Abstract

The utility model discloses the synchronous transfer devices of a kind of positioning of the concave surface of 3D bend glass and convex surface, comprising: the synchronous transfer assembly in convex surface；And blanking component and concave surface jig component set on the synchronous transfer assembly side in convex surface.According to the utility model, feeding and blanking action are integrated into an entirety by it, not only reduce structural volume, also enable feeding operation to cooperate with blanking operation and synchronizes operation, the process that originally act progress in two steps, which is integrated into, only needs a movement that can reach equivalent effect, substantially increase feeding and blanking efficiency, furthermore, it can not only carry out 3D bend glass to be accurately positioned and stablize fixing, sufficiently support can also be provided the concave surface of 3D bend glass, improve the location efficiency and effect to 3D bend glass, and then improve the compound film quality of 3D bend glass, reduce breakage rate of the 3D bend glass in coating process, finally improve the overlay film efficiency and compound film quality of 3D convex.

Description

A kind of synchronous transfer device of concave surface positioning and convex surface of 3D bend glass

Technical field

The utility model relates to 3D bend glass overlay film field, in particular to the concave surface of a kind of 3D bend glass positioning and convex Face synchronizes transfer device.

Background technique

The glass cover-plate used on smart terminal product display on existing market can be divided into: 2D glass, 2.5D glass and 3D bend glass, wherein the pure flat surface glass of 2D glass, that is, common, without any cambered design；It is flat that 2.5D glass is then intermediate Face design, edge use cambered design；Then intermediate and marginal portion may be designed to curved arc to 3D bend glass.3D is bent Surface glass mainly be bent using hot-bending machine, can achieve higher crooked radian, some physics of 3D bend glass Characteristic is substantially better than 2D and 2.5D glass.3D bend glass has frivolous, transparent cleaning, anti-fingerprint, anti-dazzle, hard, scratch resistance Wound, the advantages that weatherability is good, can not only promote the novel appearance of smart terminal product, can also bring outstanding touch-control hand Sense brings preferably display and touch experience.

The technique of 3D bend glass production at present mainly has: sawing sheet, CNC, grinding and polishing, baking, plated film, hot bending etc., In one of coating technique is also connect after hot bending process, i.e., the 3D bend glass bumps two sides (also referred to as positive and negative two after hot bending Face) protective film is enclosed, this technique is more crucial, restricts the height of yields to a certain extent.In general, in 3D curved surface glass In the coating technique of glass, the processes such as experience feeding-transfer-front overlay film-transfer overturning-back side overlay film-blanking are generally required, and In the coating processes of convex surface, the transfer and blanking of 3D glass are more crucial, directly affect the overlay film efficiency of 3D convex and cover Film quality.

In existing positioning and transfer device, there are the following problems: firstly, the degree of automation is low, needing artificial auxiliary The step of helping is more, thus leads to transfer and blanking inefficiency, workpiece is in transfer and blanking process vulnerable to pollution and damage It ruins；Secondly, common processing mode is that feeding step and blanking step are divided into two mould groups to carry out operation in the market, this is just led It causes two mould groups that cannot accomplish complete work compound, so as to cause feeding and blanking inefficiency, or even the accident of delay machine occurs, Directly affect the overlay film efficiency and compound film quality of 3D convex；Again, to the fixed unstable of 3D bend glass, lead to overlay film mistake Play phenomenon all around can occur for 3D bend glass in journey, so that there are more gas with glass surface for protective film after overlay film Hole influences compound film quality；Finally, the concave surface supporting degree to 3D bend glass is insufficient, on the one hand can make in coating process, 3D Bend glass bursts, and the concave surface that other hand will lead to 3D bend glass is deformed or scratch.

In view of this, it is really necessary to develop a kind of synchronous transfer device of concave surface positioning and convex surface of 3D bend glass, to It solves the above problems.

Utility model content

For the shortcomings of the prior art, the purpose of the utility model is to provide a kind of the recessed of 3D bend glass The synchronous transfer device of face positioning and convex surface, is integrated into an entirety for feeding and blanking action, not only reduces structural volume, Also enable feeding operation to cooperate with blanking operation and synchronize operation, the process that originally acted progress in two steps is integrated To only needing a movement that can reach equivalent effect, feeding and blanking efficiency are substantially increased, in addition, it can not only be to 3D song Surface glass be accurately positioned and stablize fixing, additionally it is possible to provide sufficiently support to the concave surface of 3D bend glass, improve to 3D The location efficiency and effect of bend glass, and then the compound film quality of 3D bend glass is improved, it reduces 3D bend glass and is covering Breakage rate in membrane process finally improves the overlay film efficiency and compound film quality of 3D convex.

In order to realize above-mentioned purpose according to the present utility model and other advantages, a kind of concave surface of 3D bend glass is provided The synchronous transfer device of positioning and convex surface, comprising:

Convex surface synchronizes transfer assembly；And

The blanking component and concave surface jig component of transfer assembly side are synchronized set on convex surface,

Wherein, blanking component and concave surface jig component are located at the ipsilateral of the synchronous transfer assembly in convex surface, and blanking component includes edge Linearly extended conveyer frames, the blanking conveyer belt on conveyer frames and for driving blanking conveyer belt linearly to transmit Blanking driver, the direction of transfer of concave surface jig component and blanking conveyer belt is conllinear and is located at the upstream of conveyer frames.

Preferably, concave surface jig component includes:

Set on the second support of the synchronous transfer assembly side in convex surface；And

The concave surface jig supported by the second support,

Wherein, the upper surface of concave surface jig is formed with bearing boss, and the front side or rear side of the bearing boss offers side Portion's limiting slot, the left or right side of the bearing boss offer end limiting slot, are equipped in the limiting slot of side for 3D is bent Surface glass pushes the second side positioning push block of the other side to, is equipped in the limiting slot of end for pushing 3D bend glass to the other end The second end positioning push block.

Preferably, the front side wall and rear wall of the bearing boss are respectively formed with preceding arc surface and rear arc surface, In, preceding arc surface and rear arc surface are adapted with the concave surface front and back sides of 3D bend glass respectively, the left side of the bearing boss The carrying cambered surface being adapted with the concave surface end of 3D bend glass is formed on wall or right side wall.

Preferably, the lower half of the adjacent two sides of the bearing boss is formed with skirt section, and skirt section is convex in the carrying The bearing boss is integrally combined on the periphery of platform and is extended outwardly from the periphery of the bearing boss, on skirt section integrally It is formed with and the carrying opposite end limiting stand of cambered surface and the side limiting stand opposite with preceding arc surface or rear arc surface.

Preferably, the synchronous transfer assembly in convex surface includes:

Second straight line guide rail extending in a straight line；

With the second mounting rack of second straight line guide rail sliding mating；And

The the second absorption migration mould group and transfer rotating module being arranged at intervals on the second mounting rack,

Wherein, the side of second straight line guide rail is equipped with for driving the second mounting rack along second straight line guide rail toward polyslip Second straight line driver, the second absorption migration mould group and transfer rotating module can selective synchronization liftings in perpendicular.

Preferably, the second absorption migration mould group includes:

The third lifting cylinder being fixedly installed on the second mounting rack；

The third sucker mounting rack being sequentially connected with the power output end of third lifting cylinder；And

Several third suckers on third sucker mounting rack lower surface,

Wherein, the orientation of several third suckers is consistent with the extending direction of second straight line guide rail.

Preferably, third sucker mounting rack structure in T shape, the root of third sucker mounting rack and third lifting cylinder Power output end transmission connection, the left and right ends of third sucker mounting rack are respectively equipped with third sucker.

Preferably, the transfer rotating module includes:

The 4th lifting cylinder being fixedly installed on the second mounting rack；

The 4th sucker mounting rack being sequentially connected with the power output end of the 4th lifting cylinder；And

Several the 4th suckers on the 4th sucker mounting rack,

Wherein, the orientation of several the 4th suckers is parallel with the extending direction of second straight line guide rail, the 4th sucker Number it is consistent with the number of third sucker.

Preferably, the 4th sucker mounting rack is equipped with rotary cylinder, and the power output end of the rotary cylinder is straight down It is sequentially connected after extending across the 4th sucker mounting rack with the 4th sucker.

Preferably, the side of the 4th sucker mounting rack is connected with the 4th bounce cylinder, the buffering of the 4th bounce cylinder End is straight down.

The utility model compared with prior art, the beneficial effect is that: its by feeding and blanking action be integrated into one it is whole Body, not only reduces structural volume, also enables feeding operation to cooperate with blanking operation and synchronizes operation, will originally divide The process that two-step action carries out, which is integrated into, only needs a movement that can reach equivalent effect, substantially increases feeding and blanking effect Rate, in addition, it can not only carry out 3D bend glass to be accurately positioned and stablize fixing, additionally it is possible to the concave surface of 3D bend glass Sufficiently support is provided, improves the location efficiency and effect to 3D bend glass, and then improve the overlay film matter of 3D bend glass Amount, reduces breakage rate of the 3D bend glass in coating process, finally improves the overlay film efficiency and overlay film of 3D convex Quality.

Detailed description of the invention

Fig. 1 is the three-dimensional according to the synchronous transfer device of the positioning of the concave surface of 3D bend glass described in the utility model and convex surface Topology view；

Fig. 2 is according to convex surface in the synchronous transfer device of the positioning of the concave surface of 3D bend glass described in the utility model and convex surface The three-dimensional structure view of synchronous transfer assembly；

Fig. 3 is according to convex surface in the synchronous transfer device of the positioning of the concave surface of 3D bend glass described in the utility model and convex surface The front view of synchronous transfer assembly；

Fig. 4 is according to concave surface in the synchronous transfer device of the positioning of the concave surface of 3D bend glass described in the utility model and convex surface The three-dimensional structure view of jig component；

Fig. 5 is according to concave surface in the synchronous transfer device of the positioning of the concave surface of 3D bend glass described in the utility model and convex surface The left view of jig component；

Fig. 6 is according to concave surface in the synchronous transfer device of the positioning of the concave surface of 3D bend glass described in the utility model and convex surface The top view of jig component；

Fig. 7 is according to concave surface in the synchronous transfer device of the positioning of the concave surface of 3D bend glass described in the utility model and convex surface The three-dimensional structure view of jig.

Specific embodiment

The following describes the utility model in further detail with reference to the accompanying drawings, the aforementioned and other mesh of the utility model , features, aspects and advantages will be apparent, to enable those skilled in the art's refer to the instruction text real accordingly It applies.In the accompanying drawings, for clarity, shape and size can be amplified, and identical attached drawing mark will be used in all figures Note is to indicate the same or similar component.In the following description, such as center, thickness, height, length, front, back, rear portion, The words such as the left side, the right, top, bottom, top, lower part are to be based on the orientation or positional relationship shown in the drawings.Particularly, " high Degree " is equivalent to size from the top to the bottom, and " width " is equivalent to size from left to right, and " depth " is equivalent to be arrived in the past Size afterwards.These relative terms are to be not intended to need specifically to be orientated for convenience and usually.Be related to attachment, Connection etc. term (for example, " connection " and " attachment ") refer to these structures pass through intermediate structure directly or indirectly to one another fixation or The relationship of attachment and movable or rigidly attached or relationship, unless otherwise clearly stating.

The concave surface of referring to Fig.1~Fig. 7,3D bend glass positions and the synchronous transfer device in convex surface includes:

Convex surface synchronizes transfer assembly 12；And

The blanking component 121 and concave surface jig component 18 of 12 side of transfer assembly are synchronized set on convex surface,

Wherein, blanking component 121 and concave surface jig component 18 are located at ipsilateral, the blanking component of the synchronous transfer assembly 12 in convex surface 121 including conveyer frames 1211 extending in a straight line, the blanking conveyer belt 1212 on conveyer frames 1211 and for driving blanking The blanking driver 1213 that conveyer belt 1212 linearly transmits, the biography of concave surface jig component 18 and blanking conveyer belt 1212 It send direction conllinear and is located at the upstream of conveyer frames 1211.In a preferred embodiment, blanking driver 1213 and blanking transmit Band 1212 realizes transmission connection by a driving belt 1214.

Referring to Fig. 4~Fig. 7, concave surface jig component 18 includes:

Set on the second support 181 of synchronous 12 side of transfer assembly in convex surface；And

The concave surface jig 182 supported by the second support 181,

Wherein, the upper surface of concave surface jig 182 is formed with bearing boss, and the front side or rear side of the bearing boss offers Side limiting slot 1822, the left or right side of the bearing boss offer end limiting slot 1828, in side limiting slot 1822 Equipped with the second side positioning push block 1841 for 3D bend glass to be pushed to the other side, it is equipped with and is used in end limiting slot 1828 3D bend glass is pushed to the second end positioning push block 1831 of the other end.

Referring to Fig. 7, the front side wall and rear wall of the bearing boss are respectively formed with preceding arc surface 1822 and rear arc surface 1823, wherein preceding arc surface 1822 and rear arc surface 1823 are adapted with the concave surface front and back sides of 3D bend glass respectively, described The carrying cambered surface being adapted with the concave surface end of 3D bend glass is formed on the left side wall or right side wall of bearing boss 1827。

Further, the lower half of the adjacent two sides of the bearing boss is formed with skirt section 1824, and skirt section 1824 is in institute It states and integrally combines the bearing boss on the periphery of bearing boss and extend outwardly from the periphery of the bearing boss, skirt section Be integrally formed on 1824 with the opposite end limiting stand 1824 of carrying cambered surface 1827 and with preceding arc surface 1822 or after The opposite side limiting stand 1825 of arc surface 1823.

Further, between the periphery of end limiting stand 1824 and side limiting stand 1825 apart from the bearing boss is certain Gap is to form the accommodation space for accommodating 3D bend glass end and side.In a preferred embodiment, the receiving is empty Between spacing not less than the thickness after 3D bend glass hot bending.

In a preferred embodiment, side limiting slot 1822 is set to the rear side of the bearing boss, side limiting stand 1825 is opposite with the front side of the bearing boss.End limiting slot 1828 is set to the right side of the bearing boss, carries cambered surface 1827 are set to the left side of the bearing boss.

Referring again to Fig. 7, several are offered on the top surface of the bearing boss and second vacuumizes hole 1826.

In a preferred embodiment, the inside of the second side positioning push block 1841 and the second end positioning push block 1831 It is equipped with elastic buffering pad, the bottom of concave surface jig 182 is equipped with the second side for driving the second side positioning push block 1841 Driver 184 and the second end driver 183 for driving the second end positioning push block 1831.

Further, the bottom of concave surface jig 182 is equipped with the second vacuum generator that connection second vacuumizes hole 1826 185。

When work, the bearing boss will be put into the posture that the 3D bend glass of overlay film is downward with concave surface, convex surface is upward On, the second side positioning push block 1841 and the second end positioning push block 1831 are respectively in the second side driver 184 and second end Push the 3D bend glass to side limiting stand 1825 and end limiting stand 1824 respectively under the driving of portion's driver 183, with reality Now to the positioning of the 3D bend glass, after the completion of positioning, several second vacuumize hole 1826 and start to be evacuated to vacuum with by 3D song The concave surface of surface glass, which is adsorbed, to be fixed, in order to carry out film coating operation to convex surface.

Referring to Fig. 2 and Fig. 3, the synchronous transfer assembly 12 in convex surface includes:

Second rack 122；

Second straight line guide rail 123 in the second rack 122, along linear extension；

With the second mounting rack 124 of the sliding mating of second straight line guide rail 123；And

The the second absorption migration mould group 125 and transfer rotating module 126 being arranged at intervals on the second mounting rack 124,

Wherein, the side of second straight line guide rail 123 is equipped with for driving the second mounting rack 124 along second straight line guide rail 123 Toward the second straight line driver 127 of polyslip, the second absorption migration mould group 125 can put down vertically with transfer rotating module 126 Selective synchronization lifting in face.

Referring to Fig. 2, the second absorption migration mould group 125 includes:

The third lifting cylinder 1251 being fixedly installed on the second mounting rack 124；

The third sucker mounting rack 1252 being sequentially connected with the power output end of third lifting cylinder 1251；And

Several third suckers 1253 on 1252 lower surface of third sucker mounting rack,

Wherein, the orientation of several third suckers 1253 is consistent with the extending direction of second straight line guide rail 123.

Further, the structure in T shape of third sucker mounting rack 1252, the root of third sucker mounting rack 1252 and the The power output end of three lifting cylinders 1251 is sequentially connected, and the left and right ends of third sucker mounting rack 1252 are respectively equipped with third Sucker 1253.

Further, the side of third sucker mounting rack 1252 is connected with the second bounce cylinder 1254, bounce cylinder 1254 Buffering end be arranged straight down.

Referring to Fig.1, the transfer rotating module 126 includes:

The 4th lifting cylinder 1261 being fixedly installed on the second mounting rack 124；

The 4th sucker mounting rack 1262 being sequentially connected with the power output end of the 4th lifting cylinder 1261；And

Several the 4th suckers 1265 on the 4th sucker mounting rack 1262,

Wherein, the orientation of several the 4th suckers 1265 is parallel with the extending direction of second straight line guide rail 123, the The number of four suckers 1265 is consistent with the number of third sucker 1253.

Further, the 4th sucker mounting rack 1262 is equipped with rotary cylinder 1263, and the power of the rotary cylinder 1263 is defeated Outlet is sequentially connected after extending across the 4th sucker mounting rack 1262 straight down with the 4th sucker 1265.

Further, the side of the 4th sucker mounting rack 1262 is connected with the 4th bounce cylinder 1264, the 4th buffering gas The buffering end of cylinder 1264 is straight down.

When work, 3D bend glass to overlay film at feeding station convex surface upward, concave surface downward, after the completion of overlay film, 3D Bend glass is placed on blanking conveyer belt and sends out.Work step:

S1, second straight line driver 127 drive the second mounting rack 124 to be moved to second straight line along second straight line guide rail 123 The front end of guide rail 123 is so that the second absorption migration mould group 125 is moved at feeding station, and third sucker 1253 is by first 3D Bend glass picks up；

S2, second straight line driver 127 drive the second mounting rack 124 be moved to second straight line guide rail 123 end so that The surface that the second absorption migration mould group 125 is moved to concave surface jig 182 is obtained, third sucker 1253 is bent by first 3D of absorption Surface glass is put into concave surface jig 182 and waits overlay film；

S3, after the completion of first 3D bend glass overlay film, second straight line driver 127 drives 124 edge of the second mounting rack Second straight line guide rail 123 is moved to the front end of second straight line guide rail 123 so that the second absorption migration mould group 125 and transfer rotation Mould group 126 is moved to the surface of at feeding station and concave surface jig 182 respectively, at this point, third sucker 1253 is by second batch 3D Bend glass picks up, and the 4th sucker 1265 picks up first 3D bend glass；

S4, second straight line driver 127 drive the second mounting rack 124 be moved to second straight line guide rail 123 end so that It obtains the second absorption migration mould group 125 and shifts surface and blanking component that rotating module 126 is moved to concave surface jig 182 respectively At 121, the second batch 3D bend glass of absorption is put into concave surface jig 182 and waits overlay film, the 4th sucker by third sucker 1253 1265 be rotated by 90 ° under the driving of rotary cylinder 1263 after first 3D bend glass is put to waiting on blanking conveyer belt 1212 Transmission；

S5, step S1~S4 is repeated, until completing the convex surface film coating operation of all 3D bend glasses.

Number of devices and treatment scale described herein are the explanations for simplifying the utility model.To the utility model Application, modifications and variations will be readily apparent to persons skilled in the art.

Although the embodiments of the present invention have been disclosed as above, it is not limited in institute in specification and embodiments Column use, it can be applied to various fields suitable for the present invention completely, for those skilled in the art, can Easily realize other modification, therefore without departing from the general concept defined in the claims and the equivalent scope, this is practical It is novel to be not limited to specific details and legend shown and described herein.

Claims (10)

1. a kind of concave surface of 3D bend glass positions and the synchronous transfer device in convex surface characterized by comprising

Convex surface is synchronous transfer assembly (12)；And

Blanking component (121) and concave surface jig component (18) set on synchronous transfer assembly (12) side in convex surface,

Wherein, blanking component (121) and concave surface jig component (18) are located at ipsilateral, the blanking group of the synchronous transfer assembly (12) in convex surface Part (121) includes conveyer frames extending in a straight line (1211), the blanking conveyer belt (1212) being set on conveyer frames (1211) and uses In the blanking driver (1213) that driving blanking conveyer belt (1212) linearly transmits, concave surface jig component (18) and blanking The direction of transfer of conveyer belt (1212) is conllinear and is located at the upstream of conveyer frames (1211).

2. the concave surface of 3D bend glass as described in claim 1 positions and the synchronous transfer device in convex surface, which is characterized in that concave surface Jig component (18) includes:

Set on second support (181) of synchronous transfer assembly (12) side in convex surface；And

The concave surface jig (182) supported by the second support (181),

Wherein, the upper surface of concave surface jig (182) is formed with bearing boss, and the front side or rear side of the bearing boss offers side Portion's limiting slot, the left or right side of the bearing boss offer end limiting slot (1828), are equipped with and are used in the limiting slot of side 3D bend glass pushed to the second side positioning push block (1841) of the other side, is equipped in end limiting slot (1828) for by 3D Bend glass pushes the second end positioning push block (1831) of the other end to.

3. the concave surface of 3D bend glass as claimed in claim 2 positions and the synchronous transfer device in convex surface, which is characterized in that described The front side wall and rear wall of bearing boss are respectively formed with preceding arc surface (1822) and rear arc surface (1823), wherein preceding circular arc Face (1822) and rear arc surface (1823) are adapted with the concave surface front and back sides of 3D bend glass respectively, a left side for the bearing boss The carrying cambered surface (1827) being adapted with the concave surface end of 3D bend glass is formed on side wall or right side wall.

4. the concave surface of 3D bend glass as claimed in claim 3 positions and the synchronous transfer device in convex surface, which is characterized in that described The lower half of the adjacent two sides of bearing boss is formed with skirt section, and skirt section integrally combines on the periphery of the bearing boss The bearing boss and extend outwardly from the periphery of the bearing boss, has been integrally formed on skirt section and carrying cambered surface (1827) Opposite end limiting stand (1824) and with preceding arc surface (1822) or the opposite side limiting stand of rear arc surface (1823) (1825)。

5. the concave surface of 3D bend glass as described in claim 1 positions and the synchronous transfer device in convex surface, which is characterized in that convex surface Synchronous transfer assembly (12) include:

Second straight line guide rail (123) extending in a straight line；

With the second mounting rack (124) of second straight line guide rail (123) sliding mating；And

The the second absorption migration mould group (125) and transfer rotating module (126) being arranged at intervals on the second mounting rack (124),

Wherein, the side of second straight line guide rail (123) is equipped with for driving the second mounting rack (124) along second straight line guide rail (123) toward the second straight line driver (127) of polyslip, the second absorption migration mould group (125) and transfer rotating module (126) are equal It can selective synchronization lifting in perpendicular.

6. the concave surface of 3D bend glass as claimed in claim 5 positions and the synchronous transfer device in convex surface, which is characterized in that second Absorption migration mould group (125) includes:

The third lifting cylinder (1251) being fixedly installed on the second mounting rack (124)；

The third sucker mounting rack (1252) being sequentially connected with the power output end of third lifting cylinder (1251)；And

Several third suckers (1253) on third sucker mounting rack (1252) lower surface,

Wherein, the orientation of several third suckers (1253) is consistent with the extending direction of second straight line guide rail (123).

7. the concave surface of 3D bend glass as claimed in claim 6 positions and the synchronous transfer device in convex surface, which is characterized in that third Sucker mounting rack (1252) structure in T shape, root and third lifting cylinder (1251) of third sucker mounting rack (1252) Power output end transmission connection, the left and right ends of third sucker mounting rack (1252) are respectively equipped with third sucker (1253).

8. the concave surface of 3D bend glass as claimed in claim 5 positions and the synchronous transfer device in convex surface, which is characterized in that described Shifting rotating module (126) includes:

The 4th lifting cylinder (1261) being fixedly installed on the second mounting rack (124)；

The 4th sucker mounting rack (1262) being sequentially connected with the power output end of the 4th lifting cylinder (1261)；And

Several the 4th suckers (1265) on the 4th sucker mounting rack (1262),

Wherein, the orientation of several the 4th suckers (1265) is parallel with the extending direction of second straight line guide rail (123), the The number of four suckers (1265) is consistent with the number of third sucker (1253).

9. the concave surface of 3D bend glass as claimed in claim 8 positions and the synchronous transfer device in convex surface, which is characterized in that the 4th Sucker mounting rack (1262) is equipped with rotary cylinder (1263), and the power output end of the rotary cylinder (1263) extends straight down And it passes through the 4th sucker mounting rack (1262) and is sequentially connected afterwards with the 4th sucker (1265).

10. the concave surface of 3D bend glass as claimed in claim 8 positions and the synchronous transfer device in convex surface, which is characterized in that the The side of four sucker mounting racks (1262) is connected with the 4th bounce cylinder (1264), the buffering end of the 4th bounce cylinder (1264) Straight down.