CN210945389U - Auxiliary production device for 3D glass sheets - Google Patents

Abstract

The utility model belongs to the technical field of 3D glass production equipment, in particular to a 3D glass sheet auxiliary production device, which comprises a feeding mechanism, a plane glass sheet cleaning mechanism, a moving mechanism, a mould cleaning mechanism and a discharging mechanism, wherein the plane glass sheet cleaning mechanism is used for cleaning a plane glass sheet, the feeding mechanism is used for conveying the plane glass sheet to the plane glass sheet cleaning mechanism, the mould cleaning mechanism is used for cleaning a mould, the plane glass sheet cleaning mechanism and the mould cleaning mechanism are both positioned in a moving area of the moving mechanism, the moving mechanism is used for assembling the cleaned plane glass sheet into the cleaned mould to form a mould to be processed, the discharging mechanism is arranged close to a discharge port of a hot press and is used for loading the 3D glass sheet which is subjected to hot press molding, the moving mechanism is used for transferring the mould to be processed to a feed port of the hot press, and is also used for grabbing the mould which is subjected to hot press to the mould cleaning mechanism and the 3D glass sheet to the, the processing efficiency is high, and manual participation is greatly saved.

Description

Auxiliary production device for 3D glass sheets

Technical Field

The utility model belongs to the technical field of 3D glass production facility, especially, relate to a 3D glass piece auxiliary production device.

Background

When 3D glass is produced, a hot pressing processing mode is generally adopted, that is, a glass sheet is placed in a 3D graphite mold, and a combined mold is placed in a hot press to process the planar glass into 3D glass in combination with the softening temperature of the glass and the mold extrusion deformation. In the prior art, before 3D glass is produced and processed, it is necessary to separately clean the flat glass and/or the mold (wherein, the mold generally includes an upper mold body and a lower mold body), then manually assemble the cleaned flat glass, the upper mold body and the lower mold body into a mold whole to be processed, place the mold whole in a hot press for processing, then manually perform blanking, and so on. In the process, not only is the related operation carried out by manpower beside the high-temperature and high-pressure hot press at a higher safety risk, but also the processing efficiency is low due to independent operation among all the working procedures and more manpower participation, and the large-batch production is not facilitated.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a 3D glass piece auxiliary production device, when aiming at solving production 3D glass among the prior art, technical problem that production efficiency is low.

In order to achieve the above object, the utility model adopts the following technical scheme: the utility model provides a 3D glass piece auxiliary production device, includes feed mechanism, plane glass piece wiper mechanism, moving mechanism, mould wiper mechanism and unloading mechanism, plane glass piece wiper mechanism is used for wasing plane glass piece, feed mechanism is used for carrying plane glass piece extremely plane glass piece wiper mechanism department, mould wiper mechanism is used for washing the mould, plane glass piece wiper mechanism with mould wiper mechanism all is located in moving region of moving mechanism, moving mechanism is used for assembling the abluent plane glass piece to the abluent mould of treating is formed in the mould, unloading mechanism is close to the discharge gate setting of hot press and is used for loading through hot briquetting's 3D glass piece, moving mechanism be used for with treat that the mould of processing transports to the feed inlet of hot press, still be used for accomplishing the hot pressing the mould snatch to on the mould wiper mechanism and with the 3D glass piece snatchs And the blanking mechanism.

Optionally, the feeding mechanism comprises a first conveying assembly and a first grabbing assembly, the first conveying assembly is used for conveying the plane glass sheet, and the first grabbing assembly is located above the first conveying assembly and used for grabbing the plane glass sheet on the first conveying assembly to the plane glass sheet cleaning mechanism.

Optionally, the first conveying assembly comprises a first screw rod module and a first trough seat, the driving end of the first screw rod module is connected with the first trough seat and drives the first trough seat to move back and forth, and a plurality of first troughs for loading the planar glass sheets are arranged on the first trough seat.

Optionally, the first grabbing assembly includes a first traverse member, a first longitudinal moving member, a first vertical moving member and a first clamping member, a driving end of the first traverse member is connected to the first longitudinal moving member and drives the first longitudinal moving member to move in a transverse direction, a driving end of the first longitudinal moving member is connected to the first vertical moving member and drives the first vertical moving member to move in a longitudinal direction, a driving end of the first vertical moving member is connected to the first clamping member and drives the first clamping member to move in a vertical direction, and the first clamping member is used for clamping the planar glass sheet.

Optionally, the flat glass sheet cleaning mechanism comprises an electrostatic cleaning part, and a cleaning area for cleaning the flat glass sheet is arranged on the electrostatic cleaning part.

Optionally, the moving mechanism includes a second traverse piece, a second longitudinal moving piece, a second vertical moving piece, and a second grabbing assembly, a driving end of the second traverse piece is connected to the second longitudinal moving piece and drives the second longitudinal moving piece to move in the transverse direction, a driving end of the second longitudinal moving piece is connected to the second vertical moving piece and drives the second vertical moving piece to move in the longitudinal direction, a driving end of the second vertical moving piece is connected to the second grabbing assembly and drives the second grabbing assembly to move in the vertical direction, and the second grabbing assembly is configured to grab the mold, the flat glass sheet, or the 3D glass sheet.

Optionally, the second grabbing assembly comprises a second clamping piece and a first sucking piece, a clamping area for clamping the mold is arranged on the second clamping piece, the first sucking piece is arranged on the bottom wall of the clamping area, and the first sucking piece is used for sucking the plane glass sheet or the 3D glass sheet.

Optionally, the mold cleaning mechanism includes a mold cleaning assembly, the mold cleaning assembly includes a mold cleaning frame, a turnover assembly and a cleaning assembly, the cleaning assembly is installed on the mold cleaning frame, a cleaning area is arranged on the cleaning assembly, the turnover assembly is installed on the mold cleaning frame and close to the cleaning area, the turnover assembly is used for clamping the lower mold body of the mold and overturning the lower mold body of the mold to the cleaning area for cleaning, and the moving mechanism is used for transporting the upper mold body of the mold to the cleaning area for cleaning.

Optionally, mould wiper mechanism still includes the mould and transports the subassembly, the mould transports the subassembly and includes second lead screw module, transports dish, third lead screw module and mounting, the second lead screw module install in on the mould wash rack and along the length direction of mould wash rack extends, the drive end of second lead screw module with transport the dish and connect and drive transport dish round trip movement, the third lead screw module install in on the mould wash rack and with second lead screw module parallel arrangement, the drive end of third lead screw module with the mounting is connected and is driven the mounting round trip movement, transport the dish and be used for loading treat the mold processing, the mounting is used for fixing transport on the dish treat the mold processing.

Optionally, the blanking mechanism comprises a second conveying assembly and a third grabbing assembly, the third grabbing assembly is used for grabbing the 3D glass sheet and placing the 3D glass sheet into the second conveying assembly, and the second conveying assembly is used for conveying the 3D glass sheet.

Optionally, the second conveying assembly comprises a fourth screw rod module and a second trough seat, a driving end of the fourth screw rod module is connected with the second trough seat and drives the second trough seat to move back and forth, and a plurality of second troughs used for loading the 3D glass sheets are arranged on the second trough seat.

Optionally, the third grabbing assembly includes a third traverse piece, a third longitudinal moving piece, a third vertical moving piece and a second sucking piece, a driving end of the third traverse piece is connected to the third longitudinal moving piece and drives the third longitudinal moving piece to move in the transverse direction, a driving end of the third longitudinal moving piece is connected to the third vertical moving piece and drives the third vertical moving piece to move in the longitudinal direction, a driving end of the third vertical moving piece is connected to the second sucking piece and drives the second sucking piece to move in the vertical direction, and the second sucking piece is used for sucking the 3D glass sheet.

The utility model has the advantages that: the utility model discloses a 3D glass piece auxiliary production device, when producing, the feed mechanism conveys the plane glass piece to the plane glass piece cleaning mechanism for cleaning, thereby realizing the automatic feeding and cleaning operation of the plane glass piece with high efficiency; the moving mechanism drives the mould to the mould cleaning component for cleaning, thereby efficiently realizing the automatic cleaning of the mould; after all having cleaned at mould and plane glass piece, moving mechanism loads the plane glass piece in the mould and forms the mould of treating processing again, then treat that the mould of processing transports the feed inlet of subassembly to the hot press through the mould, after hot pressing is accomplished, moving mechanism takes out the 3D glass piece that hot pressing is good and transports to the unloading position of unloading mechanism, make unloading mechanism accomplish the unloading to the 3D glass piece, so accomplish the technology of processing into the 3D glass piece with the plane glass piece integratively, high machining efficiency, manual work participation has greatly been saved, and economic benefits is good.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required for the embodiments or the prior art descriptions will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without inventive labor.

Fig. 1 is a schematic structural diagram of a 3D glass sheet auxiliary production device provided by an embodiment of the present invention;

FIG. 2 is a schematic structural diagram of a feeding mechanism and a flat glass sheet cleaning mechanism of the auxiliary 3D glass sheet production device in FIG. 1;

FIG. 3 is a schematic view of the first gripper of FIG. 2;

FIG. 4 is a schematic structural diagram of a moving mechanism and a mold cleaning mechanism of the auxiliary 3D glass sheet production device in FIG. 1;

FIG. 5 is a schematic diagram of the mold cleaning mechanism of FIG. 4;

FIG. 6 is a schematic structural view of the second grasping element of FIG. 4;

FIG. 7 is a schematic diagram of an application state structure of the second grasping element shown in FIG. 4;

FIG. 8 is a schematic structural diagram of a blanking mechanism of the auxiliary 3D glass sheet production device in FIG. 1;

FIG. 9 is a schematic view of the second suction member of FIG. 8;

fig. 10 is an operation step diagram of the auxiliary 3D glass sheet production apparatus provided by the embodiment of the present invention.

Wherein, in the figures, the respective reference numerals:

10-a feeding mechanism;

11 — a first transport assembly; 12 — a first grasping element; 111-a first lead screw module; 112-a first chute base; 113-a first trough; 121 — a first traverse member; 122 — a first longitudinal movement member; 123-a first vertical moving piece; 124-a first gripper; 125-a first rotating member; 1121 — first loading base; 1122 — a first lateral stop; 1123 — a first bottom brace; 1124 — a first mounting plate;

20-a flat glass sheet cleaning mechanism;

21-electrostatic cleaning part; 22-a washing zone;

30-a moving mechanism;

31 — a second traverse member; 32-a second longitudinal movement member; 33-a second vertical displacement member; 34 — a second grasping element; 341-second gripping member; 342 — a first suction element; 343-a clamping zone;

40-a mould cleaning mechanism;

41-a mould cleaning assembly; 42-a mold transfer assembly; 411-mold wash rack; 412-flip assembly; 413-a scrubbing member; 414-a brushing zone; 415-a transmission assembly; 421-a second screw rod module; 422-transport plate; 423-third screw rod module; 424 — a fixing member;

50-a blanking mechanism;

51 — a second transport assembly; 52 — a third grasping element; 511-a fourth screw module; 512-a second trough seat; 513-second material groove; 521-a third traverse member; 522 — third longitudinal movement member; 523-third vertical shift piece; 524 — second suction; 525-a second rotating member; 5121 — a second loading base; 5122-second lateral stop bar; 5123-a second bottom brace; 5124 — a second mounting plate;

60-a flat glass sheet;

70-a mould; 70a, a die to be processed;

71, mounting a die body; 72-lower die body;

80-3D glass sheet.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to fig. 1 to 10 are exemplary and intended to be used for explaining the present invention, and should not be construed as limiting the present invention.

In the description of the present invention, it is to be understood that the terms "length", "width", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on those shown in the drawings, and are merely for convenience of description and simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically limited otherwise.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," and "fixed" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

As shown in fig. 1 and 10, the embodiment of the utility model provides a 3D glass piece auxiliary production device is applied to the in-process of producing 3D glass piece 80, carries out automatic feeding and washing to plane glass piece 60 to and carry out self-cleaning, equipment and dismantlement to mould 70, accomplish the 3D glass piece 80 production process of automatic integration. Specifically, the auxiliary 3D glass sheet production device comprises a feeding mechanism 10, a flat glass sheet cleaning mechanism 20, a moving mechanism 30, a mold cleaning mechanism 40 and a discharging mechanism 50, wherein the flat glass sheet cleaning mechanism 20 is used for cleaning a flat glass sheet 60, the feeding mechanism 10 is used for conveying the flat glass sheet 60 to the flat glass sheet cleaning mechanism 20, the mold cleaning mechanism 40 is used for cleaning a mold 70, the flat glass sheet cleaning mechanism 20 and the mold cleaning mechanism 40 are both positioned in a moving area of the moving mechanism 30 (wherein the moving area is a stroke range acted by the moving mechanism 30), the moving mechanism 30 is used for assembling the cleaned flat glass sheet 60 into the cleaned mold 70 to form a mold 70a to be processed, the discharging mechanism 50 is arranged close to a discharge port of a hot press and used for loading the hot-press-formed 3D glass sheet 80, the moving mechanism 30 is used for transferring the mold 70a to be processed to the feed port of the hot press, and is also used for grabbing the hot-pressed mold 70 onto the mold cleaning mechanism 40 and grabbing the 3D glass sheet 80 onto the blanking mechanism 50.

The embodiment of the utility model provides a following is to the supplementary apparatus for producing of 3D glass piece does further explain: in the auxiliary 3D glass sheet production device according to the embodiment of the present invention, during production, the feeding mechanism 10 first conveys the planar glass sheet 60 to the planar glass sheet cleaning mechanism 20 for cleaning, so as to efficiently realize automatic feeding and cleaning operations of the planar glass sheet 60; the moving mechanism 30 drives the mold 70 to the mold cleaning assembly 41 for cleaning, so that the mold 70 can be automatically cleaned with high efficiency; after the mold 70 and the plane glass sheet 60 are cleaned, the moving mechanism 30 loads the plane glass sheet 60 in the mold 70 to form a mold 70a to be processed, then the mold 70a to be processed is transferred to a feeding hole of a hot press through the mold transfer assembly 42, after the hot pressing process is completed, the moving mechanism 30 takes out the 3D glass sheet 80 subjected to the hot pressing process and transfers the 3D glass sheet 80 to a discharging position of the discharging mechanism 50, so that the discharging mechanism 50 completes the discharging of the 3D glass sheet 80, the process of integrally processing the plane glass sheet 60 into the 3D glass sheet 80 is completed, the processing efficiency is high, manual participation is greatly omitted, and the economic benefit is good.

As shown in fig. 10, the planar glass sheet 60 is a glass sheet to be processed which needs to be placed in the mold 70 for hot press molding, and the 3D glass sheet 80 is a finished glass sheet which is subjected to hot press molding; the mold 70 includes an upper mold 71 and a lower mold 72, and when performing the hot press process, it is necessary to place the flat glass sheet 60 to be processed between the upper mold 71 and the lower mold 72 to form a mold 70a to be processed.

In one embodiment, as shown in fig. 1-2, the feeding mechanism 10 includes a first conveyor assembly 11 and a first grasping assembly 12, the first conveyor assembly 11 being configured to convey the flat glass sheet 60, the first grasping assembly 12 being positioned above the first conveyor assembly 11 and configured to grasp the flat glass sheet 60 positioned on the first conveyor assembly 11 to the flat glass sheet cleaning mechanism 20. Specifically, when the flat glass sheet 60 is loaded, an operator firstly places the flat glass sheet 60 on the first conveying assembly 11, the first grabbing assembly 12 is located above the first conveying assembly 11, and then the first conveying assembly 11 and the first grabbing assembly 12 are in mutual moving fit, so that the first grabbing assembly 12 grabs the flat glass sheet 60 on the first conveying assembly 11 to the flat glass sheet cleaning mechanism 20 for cleaning.

In one embodiment, as shown in fig. 2, the first conveying assembly 11 includes a first lead screw module 111 and a first chute base 112, a driving end of the first lead screw module 111 is connected to the first chute base 112 and drives the first chute base 112 to move back and forth, and a plurality of first chutes 113 for loading the flat glass sheet 60 are disposed on the first chute base 112. Specifically, in the process of feeding the planar glass sheet 60, the troughs are uniformly arranged along the length direction of the first trough seat 112, and each time after the first grabbing component 12 grabs the planar glass sheet 60 at the designated position, the first lead screw module 111 drives the first trough seat 112 to move forward so as to drive the planar glass sheet 60 in other first troughs 113 to move to the designated position for the first grabbing component 12 to grab, thereby realizing efficient clamping of the planar glass in the first trough seat 112. The first material groove seat 112 includes a first loading base 1121, at least two first lateral blocking bars 1122, at least one first bottom support bar 1123 and two first mounting plates 1124, the two first mounting plates 1124 are vertically mounted at two ends of the first loading base 1121, the two first lateral blocking bars 1122 are both mounted between the two first mounting plates 1124, the two first lateral blocking bars 1122 are arranged in parallel and are both located at upper portions of the two first mounting plates 1124, and first lateral clamping grooves for clamping the planar glass sheet 60 are respectively arranged at opposite sides of the two first lateral blocking bars 1122; the first bottom support bar 1123 is mounted between the two first mounting plates 1124, the first bottom support bar 1123 is located at the lower part of the two first mounting plates 1124 and between the two first lateral barrier bars 1122, and the first bottom support bar 1123 is provided with a first bottom clamping groove for supporting the planar glass sheet 60; the two first lateral blocking bars 1122 arranged oppositely form a group of lateral supporting units, and the first trough 113 is formed by enclosing the two first lateral clamping grooves and the first bottom clamping groove between the two first lateral clamping grooves.

In one embodiment, as shown in fig. 2 to 3, the first grabbing assembly 12 includes a first traverse member 121, a first longitudinal moving member 122, a first vertical moving member 123 and a first grabbing member 124, a driving end of the first traverse member 121 is connected to the first longitudinal moving member 122 and drives the first longitudinal moving member 122 to move in the transverse direction, a driving end of the first longitudinal moving member 122 is connected to the first vertical moving member 123 and drives the first vertical moving member 123 to move in the longitudinal direction, a driving end of the first vertical moving member 123 is connected to the first grabbing member 124 and drives the first grabbing member 124 to move in the vertical direction, and the first grabbing member 124 is used for grabbing the planar glass sheet 60. Specifically, when grabbing the planar glass sheet 60, the first clamping member 124 is driven to grab above the first chute seat 112; when the first clamping member 124 clamps the planar glass sheet 60, the planar glass sheet 60 is in a vertical state, and the first clamping member 124 clamps two sides of the planar glass sheet 60 right above the planar glass sheet 60, then lifts the planar glass sheet upwards in a vertical direction, and then transfers the planar glass sheet to the planar glass sheet cleaning mechanism 20 for cleaning. Wherein the first gripper 124 is preferably a pneumatic gripper; the first rotating member 125 is preferably a rotating motor; the first traverse member 121, the first longitudinal member 122 and the first vertical member 123 may be a screw rod module, a linear motor or an air floating module, and are arranged as required.

In one embodiment, as shown in FIGS. 1-2, the flat glass sheet cleaning mechanism 20 includes an electrostatic cleaning member 21, and the electrostatic cleaning member 21 is provided with a cleaning region 22 for cleaning the flat glass sheet 60. Specifically, the first grabbing assembly 12 further includes a first rotating member 125, the first rotating member 125 is connected to a driving end of the first vertical moving member 123, the first clamping member 124 is connected to a driving end of the first rotating member 125, the first rotating member 125 drives the first clamping member 124 to rotate, when the electrostatic cleaning member 21 cleans the planar glass sheet 60, the first clamping member 124 clamps the planar glass sheet 60 and vertically extends into the cleaning area 22 for cleaning, after cleaning, the first clamping member 124 drives the planar glass sheet 60 to move upwards to leave the cleaning area 22, and then the first rotating member 125 drives the first clamping member 124 to rotate 90 ° so that the planar glass sheet 60 is in a horizontal state, at this time, the first clamping member 124 drives the planar glass sheet 60 to move to a position to be processed in the mold 70 to process the planar glass sheet into the 3D glass sheet 80. Among them, the first rotating member 125 is preferably a rotating motor.

In one embodiment, as shown in fig. 1 and 4, the moving mechanism 30 includes a second traverse member 31, a second longitudinal moving member 32, a second vertical moving member 33, and a second grasping assembly 34, wherein a driving end of the second traverse member 31 is connected to the second longitudinal moving member 32 and drives the second longitudinal moving member 32 to move in the transverse direction, a driving end of the second longitudinal moving member 32 is connected to the second vertical moving member 33 and drives the second vertical moving member 33 to move in the longitudinal direction, a driving end of the second vertical moving member 33 is connected to the second grasping assembly 34 and drives the second grasping assembly 34 to move in the vertical direction, and the second grasping assembly 34 is used for grasping the mold 70, the flat glass sheet 60, or the 3D glass sheet 80. Specifically, the second traverse member 31, the second longitudinal member 32 and the second vertical member 33 cooperate with each other to move the second grabbing assembly 34 between the mold cleaning assembly 41 and the mold transferring assembly 42, so that the second grabbing assembly 34 grabs the mold 70 for cleaning in the mold cleaning assembly 41, and the second grabbing assembly 34 can also grab the cleaned flat glass sheet 60 between the upper mold body 71 and the lower mold body 72 of the mold 70 to assemble the mold 70a to be processed.

In one embodiment, as shown in fig. 6 and 7, the second grabbing component 34 comprises a second clamping member 341 and a first suction member 342, the second clamping member 341 is provided with a clamping area 343 for clamping the mold 70, the first suction member 342 is provided on the bottom wall of the clamping area 343, and the first suction member 342 is used for sucking the flat glass sheet 60 or the 3D glass sheet 80. Specifically, since the second gripper assembly 34 is provided with the second gripper 341 and the first suction member 342, and the first suction member 342 includes at least one first suction plate, each first suction plate may be configured to suck the planar glass sheet 60 and may also suck the 3D glass sheet 80. When the second grabbing assembly 34 needs to grab two objects, the first grabbing member 342 moves to a designated position first, so that the first grabbing member 342 sucks one sheet object (such as the flat glass sheet 60 or the 3D glass sheet 80) to the bottom wall of the clamping area 343 first, and then the second grabbing member 341 moves to the designated position again, so that the second grabbing member 341 grabs another block object (such as the upper mold body 71 or the lower mold body 72 of the mold 70) to clamp the block object in the clamping area 343 and to be spaced from the sheet object, thereby avoiding the two objects from interfering with each other in the clamping area 343, realizing grabbing two objects at one time, and effectively improving the transfer efficiency. Of course, when only one object needs to be grabbed, the second gripper 341 or the first gripper 342 can be correspondingly started to grab and transfer the object, and the use is flexible.

In one embodiment, as shown in fig. 4, 5 and 10, the mold cleaning mechanism 40 includes a mold cleaning assembly 41, the mold cleaning assembly 41 includes a mold cleaning frame 411, a flipping assembly 412 and a brushing member 413, the brushing member 413 is mounted on the mold cleaning frame 411, the brushing member 413 is provided with a brushing area 414, the flipping assembly 412 is mounted on the mold cleaning frame 411 and is disposed near the brushing area 414, the flipping assembly 412 is configured to hold the lower mold 72 of the mold 70 and flip the lower mold 72 of the mold 70 into the brushing area 414 for brushing, and the moving mechanism 30 is configured to transfer the upper mold 71 of the mold 70 into the brushing area 414 for brushing. Specifically, a temporary storage table is arranged on the mold cleaning rack 411, a lifting device is arranged on the temporary storage table, after the mold 70 to be processed is subjected to hot pressing in the hot press and conveyed to the temporary storage table (the mold state in this process is shown as step a in fig. 10), the temporary storage table conveys the mold 70 to a position close to the turnover assembly 412 through the lifting device, the second clamping member 341 firstly clamps the whole of the mold 70 and places the whole of the mold 70 on the turnover assembly 412, so that the turnover assembly 412 clamps and fixes the lower mold 72 of the mold 70, then the second clamping member 341 secondly clamps the upper mold 71 of the mold 70 and enters the brushing area 414 for cleaning, after the upper mold 71 of the mold 70 is cleaned, the second clamping member 341 secondly places the upper mold 71 of the mold 70 on the temporary storage table, then the first clamping member 342 secondly grabs the hot-press molded 3D glass sheet 80 to a designated position for placing for blanking, and then the turnover assembly 412 secondly places the lower mold 72 of the mold 70 into the brushing area 414 for cleaning, after the cleaning, the lower mold body 72 of the mold 70 is turned to the original state (the mold state is shown in step b in fig. 10), after the upper mold body 71 and the lower mold body 72 of the mold 70 are both cleaned, the first suction member 342 sucks the cleaned flat glass sheet 60 and places the flat glass sheet on the lower mold body 72 of the mold 70 (the mold state is shown in step c in fig. 10), then the second gripping member 341 grips the upper mold body 71 of the mold 70 and places the flat glass sheet on the lower mold body 72 of the mold 70 to form a mold 70a to be processed (the mold state is shown in step d in fig. 10), and then the second gripping member 341 grips the mold 70a to be processed on the mold transfer assembly 42 to transfer the mold transfer assembly to the feeding port of the hot press for hot press processing. Wherein, upset subassembly 412 includes roll-over seat and clamping jaw, the clamping jaw passes through cylinder drive with the lower mould body 72 of centre gripping mould 70, the roll-over seat articulates on mould wash rack 411, the roll-over seat passes through drive assembly 415 (wherein, drive assembly 415 is preferably the combination of hold-in range and synchronizing wheel, set up a synchronizing wheel on mould wash rack 411 promptly, set up a synchronizing wheel on the roll-over seat, the synchronizing belt connects between two synchronizing wheels around, the synchronizing wheel that is located on mould wash rack 411 passes through motor drive and rotates), the driving phase mold wash rack 411 that the clamping jaw is installed on the roll-over seat, the clamping jaw just can overturn when the lower mould body 72 of centre gripping mould 70 washes in the district 414 and scrub.

In one embodiment, as shown in fig. 5, the mold cleaning mechanism 40 further includes a mold transferring assembly 42, the mold transferring assembly 42 includes a second lead screw module 421, a transferring plate 422, a third lead screw module 423 and a fixing member 424, the second lead screw module 421 is mounted on the mold cleaning frame 411 and extends along the length direction of the mold cleaning frame 411, a driving end of the second lead screw module 421 is connected with the transferring plate 422 and drives the transferring plate 422 to move back and forth, the third lead screw module 423 is mounted on the mold cleaning frame 411 and is arranged in parallel with the second lead screw module 421, a driving end of the third lead screw module 423 is connected with the fixing member 424 and drives the fixing member 424 to move back and forth, the transferring plate 422 is used for loading the mold 70a to be processed, and the fixing member 424 is used for fixing the mold 70a to be processed on the transferring. Specifically, the fixing member 424 is provided with a pressing plate, and the pressing plate is driven by a cylinder to move back and forth in the up-and-down direction. In the process of transferring the die 70a to be processed to the feeding hole of the hot press, the second lead screw module 421 first drives the transfer disc 422 to move to a designated position, then the second clamping member 341 places the mold 70a to be processed on the transferring plate 422, and at this time, the third screw module 423 drives the fixing member 424 to move to the position right above the transferring plate 422, the platen is then driven to press against the upper mold body 71 of the mold 70 to clamp the entire mold 70a to be processed, then the second lead screw module 421 and the third lead screw module 423 are moved simultaneously to drive the die 70a to be processed to move to the feeding hole of the hot press, after the die 70a to be processed moves to the feeding hole of the hot press, the pressing plate moves upward to be no longer pressed on the mold 70, and at this time, the third screw module 423 drives the fixing member 424 to move to the avoiding position, and then the execution part on the hot press conveys the whole die 70a to be processed into the hot press for hot pressing.

In one embodiment, as shown in fig. 1 and 8, the blanking mechanism 50 includes a second conveying assembly 51 and a third grabbing assembly 52, the third grabbing assembly 52 is used for grabbing the 3D glass sheet 80 and placing the 3D glass sheet into the second conveying assembly 51, and the second conveying assembly 51 is used for conveying the 3D glass sheet 80. Specifically, after the first suction device 342 grabs the hot press formed 3D glass sheet 80 to a designated position for placing for blanking, the third grabbing assembly 52 starts to grab the hot press formed 3D glass sheet 80 to the second conveying assembly 51 for blanking, so that the automatic blanking of the 3D glass sheet 80 is completed, and the operation efficiency is high.

In one embodiment, as shown in fig. 8, the second conveying assembly 51 includes a fourth lead screw module 511 and a second trough base 512, a driving end of the fourth lead screw module 511 is connected to the second trough base 512 and drives the second trough base 512 to move back and forth, and a plurality of second troughs 513 for loading the 3D glass sheets 80 are disposed on the second trough base 512. Specifically, in the process of 3D glass piece 80 unloading, second silo 513 is evenly arranged along the length direction of material second silo seat 512, and every time third grabbing component 52 has sucked 3D glass piece 80 at the designated position and placed to second silo 513, fourth lead screw module 511 will drive second silo seat 512 to move, so as to move second silo 513 with 3D glass piece 80 to the avoidance position, and supply other second silos 513 without 3D glass piece 80 to load, thereby realizing loading 3D glass piece 80 into each second silo 513 on second silo seat 512 efficiently. The second material groove seat 512 comprises a second loading base 5121, at least two second lateral blocking bars 5122, at least one second bottom supporting bar 5123 and two second mounting plates 5124, the two second mounting plates 5124 are vertically mounted at two ends of the second loading base 5121, the two second lateral blocking bars 5122 are both mounted between the two second mounting plates 5124, the two second lateral blocking bars 5122 are arranged in parallel and are both located at the upper parts of the two second mounting plates 5124, and second lateral clamping grooves for clamping the 3D glass sheet 80 are respectively arranged at the opposite sides of the two second lateral blocking bars 5122; the second bottom supporting bar 5123 is installed between the two second mounting plates 5124, the second bottom supporting bar 5123 is located at the lower parts of the two second mounting plates 5124 and between the two second lateral blocking bars 5122, and a second bottom clamping groove for supporting the 3D glass sheet 80 is formed in the second bottom supporting bar 5123; two second lateral blocking bars 5122 arranged oppositely form a group of lateral supporting units, and the two second lateral clamping grooves arranged oppositely and the second bottom clamping groove arranged between the two second lateral clamping grooves are arranged together in a surrounding manner to form a second trough 513.

In one embodiment, as shown in fig. 8 and 9, the third grabbing assembly 52 includes a third traverse member 521, a third longitudinal moving member 522, a third vertical moving member 523, and a second sucking member 524, wherein a driving end of the third traverse member 521 is connected to the third longitudinal moving member 522 and drives the third longitudinal moving member 522 to move in the transverse direction, a driving end of the third longitudinal moving member 522 is connected to the third vertical moving member 523 and drives the third vertical moving member 523 to move in the longitudinal direction, a driving end of the third vertical moving member 523 is connected to the second sucking member 524 and drives the second sucking member 524 to move in the vertical direction, and the second sucking member 524 is used for sucking the 3D glass sheet 80. Specifically, the third traverse member 521, the third longitudinal member 522 and the third vertical member 523 drive the second suction member 524 to move freely within the stroke range; the second grabbing component 34 further includes a second rotating member 525, the second rotating member 525 is connected to the driving end of the second vertical moving member 33, the second sucking member 524 is connected to the driving end of the second rotating member 525, the second rotating member 525 drives the second sucking member 524 to rotate, when the 3D glass sheet 80 is grabbed, the 3D glass sheet 80 is in a horizontal state, the second rotating member 525 first drives the second sucking member 524 to rotate to the horizontal grabbing state so that the second sucking member 524 grabs the 3D glass sheet 80, after grabbing is completed, the second rotating member 525 then drives the second sucking member 524 to rotate to a vertical state so that the 3D glass sheet 80 is in a vertical state, and then the 3D glass sheet 80 is placed in the second trough 513 to complete the blanking of the 3D glass sheet 80, and the above steps are repeated. Wherein the second suction member 524 is preferably a vacuum chuck; the second rotating member 525 is preferably a rotating motor; the third horizontal moving piece 521, the third vertical moving piece 522 and the third vertical moving piece 523 can be a screw rod module, a linear motor or an air floatation module and the like and are arranged as required.

The above description is only exemplary of the present invention and should not be taken as limiting the scope of the present invention, as any modifications, equivalents, improvements and the like made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

Claims (12)

1. The utility model provides a 3D glass piece auxiliary production device which characterized in that: comprises a feeding mechanism, a plane glass sheet cleaning mechanism, a moving mechanism, a mould cleaning mechanism and a discharging mechanism, the plane glass sheet cleaning mechanism is used for cleaning the plane glass sheet, the feeding mechanism is used for conveying the plane glass sheet to the plane glass sheet cleaning mechanism, the mould cleaning mechanism is used for cleaning a mould, the plane glass sheet cleaning mechanism and the mould cleaning mechanism are both positioned in a moving area of the moving mechanism, the moving mechanism is used for assembling the cleaned plane glass sheet into the cleaned mould to form a mould to be processed, the blanking mechanism is arranged close to the discharge hole of the hot press and is used for loading the 3D glass sheet which is formed by hot pressing, the moving mechanism is used for transferring the die to be processed to a feeding hole of the hot press, and is also used for grabbing the die after hot pressing to the die cleaning mechanism and grabbing the 3D glass sheet to the discharging mechanism.

2. The apparatus for assisting in the production of a 3D glass sheet according to claim 1, wherein: the feeding mechanism comprises a first conveying assembly and a first grabbing assembly, the first conveying assembly is used for conveying the plane glass sheet, and the first grabbing assembly is located above the first conveying assembly and used for grabbing the plane glass sheet located on the first conveying assembly to the plane glass sheet cleaning mechanism.

3. The apparatus for assisting in the production of a 3D glass sheet according to claim 2, wherein: the first conveying assembly comprises a first screw rod module and a first trough seat, the driving end of the first screw rod module is connected with the first trough seat and drives the first trough seat to move back and forth, and a plurality of first troughs used for loading the plane glass sheets are arranged on the first trough seat.

4. The apparatus for assisting in the production of a 3D glass sheet according to claim 2, wherein: the first grabbing assembly comprises a first transverse moving piece, a first longitudinal moving piece, a first vertical moving piece and a first clamping piece, the driving end of the first transverse moving piece is connected with the first longitudinal moving piece and drives the first longitudinal moving piece to move transversely, the driving end of the first longitudinal moving piece is connected with the first vertical moving piece and drives the first vertical moving piece to move longitudinally, the driving end of the first vertical moving piece is connected with the first clamping piece and drives the first clamping piece to move vertically, and the first clamping piece is used for clamping the plane glass sheet.

5. The apparatus for assisting in the production of a 3D glass sheet according to claim 1, wherein: the plane glass sheet cleaning mechanism comprises an electrostatic cleaning part, and a cleaning area for cleaning the plane glass sheet is arranged on the electrostatic cleaning part.

6. The apparatus for assisting in the production of a 3D glass sheet according to any one of claims 1 to 5, wherein: the moving mechanism comprises a second transverse moving piece, a second longitudinal moving piece, a second vertical moving piece and a second grabbing assembly, the driving end of the second transverse moving piece is connected with the second longitudinal moving piece and drives the second longitudinal moving piece to move transversely, the driving end of the second longitudinal moving piece is connected with the second vertical moving piece and drives the second vertical moving piece to move longitudinally, the driving end of the second vertical moving piece is connected with the second grabbing assembly and drives the second grabbing assembly to move vertically, and the second grabbing assembly is used for grabbing the mold, the plane glass sheet or the 3D glass sheet.

7. The apparatus for assisting in the production of a 3D glass sheet according to claim 6, wherein: the second grabbing component comprises a second clamping piece and a first sucking piece, a clamping area used for clamping the mold is arranged on the second clamping piece, the first sucking piece is arranged on the bottom wall of the clamping area, and the first sucking piece is used for sucking the plane glass sheet or the 3D glass sheet.

8. The apparatus for assisting in the production of a 3D glass sheet according to any one of claims 1 to 5, wherein: the mould wiper mechanism includes the mould and washs the subassembly, the mould washs the subassembly and includes mould wash rack, upset subassembly and scrubbing piece, scrubbing piece install in on the mould wash rack, be equipped with the district of scrubbing on the scrubbing piece, the upset subassembly install in on the mould wash rack and be close to the district of scrubbing sets up, the upset subassembly is used for the centre gripping the lower die body of mould and with the lower die body upset of mould extremely scrub in the district of scrubbing, moving mechanism be used for with the last die body of mould transports extremely scrub in the district of scrubbing.

9. The apparatus for assisting in the production of a 3D glass sheet according to claim 8, wherein: the mould wiper mechanism still includes the mould and transports the subassembly, the mould transports the subassembly and includes second lead screw module, transports dish, third lead screw module and mounting, the second lead screw module install in on the mould wash rack and along the length direction of mould wash rack extends, the drive end of second lead screw module with transport the dish and connect and drive transport dish round trip movement, the third lead screw module install in on the mould wash rack and with second lead screw module parallel arrangement, the drive end of third lead screw module with the mounting is connected and is driven the mounting round trip movement, transport the dish and be used for loading treat the mold processing, the mounting is used for fixing transport on the dish treat the mold processing.

10. The apparatus for assisting in the production of a 3D glass sheet according to any one of claims 1 to 5, wherein: the blanking mechanism comprises a second conveying assembly and a third grabbing assembly, the third grabbing assembly is used for grabbing the 3D glass sheet and placing the 3D glass sheet into the second conveying assembly, and the second conveying assembly is used for conveying the 3D glass sheet.

11. The apparatus for assisting in the production of a 3D glass sheet according to claim 10, wherein: the second conveying assembly comprises a fourth screw rod module and a second trough seat, the driving end of the fourth screw rod module is connected with the second trough seat and drives the second trough seat to move back and forth, and a plurality of second troughs used for loading the 3D glass sheets are arranged on the second trough seat.

12. The apparatus for assisting in the production of a 3D glass sheet according to claim 10, wherein: the third grabbing assembly comprises a third transverse moving piece, a third longitudinal moving piece, a third vertical moving piece and a second sucking piece, the driving end of the third transverse moving piece is connected with the third longitudinal moving piece and drives the third longitudinal moving piece to move transversely, the driving end of the third longitudinal moving piece is connected with the third vertical moving piece and drives the third vertical moving piece to move longitudinally, the driving end of the third vertical moving piece is connected with the second sucking piece and drives the second sucking piece to move vertically, and the second sucking piece is used for sucking the 3D glass sheet.

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