阅读说明：本技术 一种玻璃注塑成型模具及成型机床 (Glass injection molding mould and forming machine tool ) 是由 李刚 蔡燕 肖鑫 杜建周 陈晶晶 陈普 于 2021-09-06 设计创作，主要内容包括：本发明涉及玻璃加工技术领域,提供了一种玻璃注塑成型模具及成型机床,包括供料机构、成型机构、输送辊机、过渡输送机构、支撑架、翻面机构和处理机构,所述供料机构设置在成型机构的一侧,所述输送辊机和支撑架上罩设有安装罩板,所述供料机构包括承载台、丝杆滑台、安装支架、混料组件和注塑筒体,所述承载台横设在成型机构的一侧,所述丝杆滑台安装在承载台的内顶部,所述安装支架的底部与丝杆滑台的移动端相连接,所述注塑筒体固定在安装支架上,所述安装支架上设有驱动电机,所述注塑筒体内设有加热器、螺杆和螺旋叶片,所述驱动电机的输出端通过联轴器与螺杆的一端相连接,所述螺旋叶片固定在螺杆上。(The invention relates to the technical field of glass processing, and provides a glass injection molding die and a molding machine tool, which comprise a feeding mechanism, a molding mechanism, a conveying roller machine, a transition conveying mechanism, a support frame, a turnover mechanism and a processing mechanism, wherein the feeding mechanism is arranged on one side of the molding mechanism, the conveying roller machine and the support frame are covered with installation cover plates, the feeding mechanism comprises a bearing table, a screw rod sliding table, an installation support, a mixing component and an injection molding barrel, the bearing table is transversely arranged on one side of the molding mechanism, the screw rod sliding table is arranged on the inner top of the bearing table, the bottom of the installation support is connected with the moving end of the screw rod sliding table, the injection molding barrel is fixed on the installation support, the installation support is provided with a driving motor, a heater, a screw rod and a helical blade are arranged in the injection molding barrel, the output end of the driving motor is connected with one end of the screw rod through a coupler, the helical blade is fixed on the screw rod.)

1. The utility model provides a glass injection moulding mould and forming machine, its characterized in that: comprises a feeding mechanism, a forming mechanism, a conveying roller machine, a transition conveying mechanism, a support frame, a turnover mechanism and a processing mechanism, wherein the feeding mechanism is arranged on one side of the forming mechanism, the forming mechanism is transversely arranged at the feeding end of the conveying roller machine, the transition conveying mechanism is arranged at the discharging end of the conveying roller machine, one end of the support frame is connected with the discharging end of the conveying roller machine, the turnover mechanism is arranged on the support frame, the processing mechanism is arranged at the top of the support frame, the conveying roller machine and the upper cover of the support frame are provided with an installation cover plate, the feeding mechanism comprises a bearing table, a screw rod sliding table, an installation support, a mixing component and an injection molding barrel body, the bearing table is transversely arranged on one side of the forming mechanism, the screw rod sliding table is arranged at the inner top of the bearing table, the bottom of the installation support is connected with the moving end of the screw rod sliding table, the injection molding barrel body is fixed on the installation support, the injection molding machine is characterized in that a driving motor is arranged on the mounting support, a heater, a screw and a helical blade are arranged in the injection molding barrel, the output end of the driving motor is connected with one end of the screw through a coupler, and the helical blade is fixed on the screw.

2. The glass injection molding mold and the molding machine tool according to claim 1, characterized in that: the compounding subassembly is including holding feed cylinder, rotating electrical machines, rotation axis, rotating vane, base frame, control motor, commentaries on classics board and dead axle, the base frame is fixed on the barrel of moulding plastics, it fixes on the base frame to hold the feed cylinder, the rotation axis rotates and installs in holding the feed cylinder, the rotating electrical machines is fixed and is connected with the top of rotation axis at the top of holding the feed cylinder and the output of rotating electrical machines, rotating vane fixes on the rotation axis, be equipped with on the base frame and hold the feed cylinder and the material way that the barrel is connected of moulding plastics, the dead axle rotates and sets up in the material way, change the board and fix on the dead axle, control motor installs on the lateral wall of base frame and the output of control motor is connected with the one end of dead axle.

3. The glass injection molding mold and the molding machine tool according to claim 1, characterized in that: the forming mechanism comprises a stand, a rotating module, a protective assembly, a movable template, a mounting plate, a lifting cylinder and four guide pillars, wherein the stand is transversely arranged at the feeding end of the conveying roller, the rotating module is arranged at the top of the stand, the protective assembly is arranged on the inner side wall of the stand, the guide pillars are rectangular and are vertically arranged at the top of the stand, the mounting plate is fixed on the top ends of the four guide pillars, the lifting cylinder is fixed at the top of the mounting plate, the movable template is arranged on the four guide pillars in a sliding mode, and a convex die seat detachably connected with the movable template is arranged at the bottom of the movable template.

4. The glass injection molding mold and the molding machine tool according to claim 3, characterized in that: rotate the die holder including rotating motor, bearing axle, base station and die holder, be equipped with on the pallet and supply base station pivoted to lack the groove, the bearing axle rotates and installs on the base station and be located and lack the inslot, it fixes on the lateral wall of pallet and the output that rotates the motor is connected with the one end of bearing axle to rotate the motor, the base station is fixed on the bearing axle, the die holder can be dismantled and connect on the base station.

5. The glass injection molding mold and the molding machine tool according to claim 4, characterized in that: protection component includes drive motor, transmission shaft, two carry on strip and two fixed plates, two the both sides at the pallet are installed respectively to the fixed plate, drive motor installs on a fixed plate and drive motor's output is connected with the one end of transmission shaft, the both ends of transmission shaft rotate with two fixed plates respectively and are connected, two carry on the strip and all fix on the transmission shaft.

6. The glass injection molding mold and the molding machine tool according to claim 1, characterized in that: the transition conveying mechanism comprises a transition conveying belt, a linkage motor, a horizontal plate, a linkage plate and two L-shaped clamping arms, wherein the horizontal plate is installed on one end side wall of the conveying roller machine, the linkage motor is fixed on the horizontal plate, the output end of the linkage motor is connected with the central portion of the linkage plate, the L-shaped clamping arms are symmetrically arranged on two sides of the supporting frame, one end of each L-shaped clamping arm is connected with one end of the linkage plate, and each L-shaped clamping arm slides with the supporting frame.

7. The glass injection molding mold and the molding machine tool according to claim 6, characterized in that: turn-over mechanism includes left carrier assembly, right carrier assembly and two buffering subassemblies, left side carrier assembly and right carrier assembly all install on the support frame, two the buffering subassembly symmetry sets up on left carrier assembly, left side carrier assembly includes left grid grillage, left motor and first even axle, left side motor is installed on the lateral wall of support frame and the output of left motor is connected with the one end of first axle, the one end of left side grid grillage extends to the setting of transition conveyer belt, the other end and the first axle of left side grid grillage are connected.

8. The glass injection molding mold and the molding machine tool according to claim 7, characterized in that: the right bearing assembly comprises a right grid plate frame, a right motor and a second connecting shaft, the right motor is installed on the other side wall of the supporting frame, the output end of the right motor is connected with one end of the second connecting shaft, one end of the right grid plate frame is connected with the second connecting shaft, and two suckers are arranged on the left grid plate frame and the right grid plate frame.

9. The glass injection molding mold and the molding machine tool according to claim 7, characterized in that: every buffer unit all is including taking plate, arc and first spring, take the plate to fix the one end angle department at left grid grillage, arc and first spring all set up in the take the plate, just the both ends of first spring are connected with arc and take the plate piece respectively.

10. The glass injection molding mold and the molding machine tool according to claim 1, characterized in that: the processing mechanism comprises two edging assemblies and two positioning assemblies, the two edging assemblies are symmetrically arranged on two sides of the support frame, the two positioning assemblies are symmetrically arranged on two sides of the support frame, each edging assembly comprises a first pushing cylinder, a first T-shaped plate, a fixed seat and a polishing roller, the first T-shaped plate is arranged on one side wall of the support frame, the first pushing cylinder is fixed on the first T-shaped plate, the output end of the first pushing cylinder is connected with the fixed seat, the polishing roller is rotatably arranged on the fixed seat, each positioning assembly comprises a second pushing cylinder, a second T-shaped plate, a push plate, a limiting plate and a plurality of second springs, the second T-shaped plate is arranged on one side wall of the support frame, the second pushing cylinder is fixed on the second T-shaped plate, the output end of the second pushing cylinder is connected with the push plate, and the plurality of second springs are arranged between the push plate and the limiting plate at intervals, and the two ends of each second spring are respectively connected with the push plate and the limiting plate.

Technical Field

The invention relates to the technical field of glass processing, in particular to a glass injection molding mold and a molding machine tool.

Background

Glass is an amorphous inorganic non-metallic material, and is generally prepared by using various inorganic minerals (such as quartz sand, borax, boric acid, barite, barium carbonate, limestone, feldspar, soda ash and the like) as main raw materials and adding a small amount of auxiliary raw materials. Its main components are silicon dioxide and other oxides. The chemical composition of the common glass is Na2SiO3, CaSiO3, SiO2 or Na 2O. CaO.6SiO 2, and the like, and the main component is a silicate double salt which is an amorphous solid with a random structure. Widely applied to various fields, is used for isolating wind and transmitting light, and belongs to a mixture. Colored glass in which an oxide or salt of a certain metal is mixed to develop a color, tempered glass produced by a physical or chemical method, and the like are also available. Some transparent plastics, such as polymethylmethacrylate, are sometimes also referred to as plexiglas.

When the existing glass is manufactured by injection molding, the glass integrated injection mold cannot perform continuous injection molding on the glass, the working efficiency is low, a large amount of manpower is needed for processing, the glass is heated to 300-500 ℃, the glass is softened, image surface groups are the same, the softened glass is manually processed, mass production cannot be performed, and the glass is further manually molded in the production process, such as edging, cutting and other processes, so that the production quality and efficiency of the glass are seriously affected.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide a glass injection molding mold and a molding machine tool to solve the problems that continuous injection molding of glass cannot be carried out, the working efficiency is low, softened glass cannot be produced in large batch due to manual processing, and the production quality and efficiency of the glass are seriously influenced due to the fact that the glass needs to be molded manually in the production process, such as edging, cutting and other working procedures.

In order to achieve the purpose, the invention is realized by the following technical scheme: a glass injection molding die and a molding machine tool comprise a feeding mechanism, a molding mechanism, a conveying roller machine, a transition conveying mechanism, a support frame, a turnover mechanism and a processing mechanism, wherein the feeding mechanism is arranged on one side of the molding mechanism, the molding mechanism is transversely arranged at the feeding end of the conveying roller machine, the transition conveying mechanism is arranged at the discharging end of the conveying roller machine, one end of the support frame is connected with the discharging end of the conveying roller machine, the turnover mechanism is arranged on the support frame, the processing mechanism is arranged at the top of the support frame, the conveying roller machine and the support frame are covered with an installation cover plate, the feeding mechanism comprises a bearing table, a screw rod sliding table, an installation support, a mixing component and an injection molding barrel body, the bearing table is transversely arranged on one side of the molding mechanism, the screw rod sliding table is arranged at the inner top of the bearing table, the bottom of the installation support is connected with the moving end of the screw rod sliding table, the injection molding machine is characterized in that the injection molding barrel is fixed on the mounting support, a driving motor is arranged on the mounting support, a heater, a screw and a helical blade are arranged in the injection molding barrel, the output end of the driving motor is connected with one end of the screw through a coupler, and the helical blade is fixed on the screw.

Preferably, the compounding subassembly is including holding feed cylinder, rotating electrical machines, rotation axis, rotating vane, base frame, control motor, commentaries on classics board and dead axle, the base frame is fixed on the barrel of moulding plastics, it fixes on the base frame to hold the feed cylinder, the rotation axis rotates and installs in holding the feed cylinder, the rotating electrical machines is fixed and is connected with the top of rotation axis at the top of holding the feed cylinder and the output of rotating electrical machines, rotating vane fixes on the rotation axis, be equipped with on the base frame and hold the feed cylinder and the material way that the barrel is connected of moulding plastics, the dead axle rotates and sets up in the material way, the commentaries on classics board is fixed on the dead axle, control motor installs on the lateral wall of base frame and the output of control motor is connected with the one end of dead axle.

Preferably, forming mechanism includes the pallet, rotates the module, protection component, movable mould board, mounting panel, lift cylinder and four guide pillars, the pallet is violently established at the pan feeding end department of conveyor roll machine, it installs at the top of pallet to rotate the module, protection component installs on the inside wall of pallet, four the guide pillar is the vertical top of installing at the pallet of rectangle, the mounting panel is fixed on the top of four guide pillars, the top at the mounting panel is fixed to the lift cylinder, the movable mould board slides and sets up on four guide pillars, the bottom of movable mould board is equipped with rather than can dismantling the convex die seat of being connected.

Preferably, the rotating die holder comprises a rotating motor, a bearing shaft, a base station and a die holder, a groove for rotating the base station is formed in the stand, the bearing shaft is rotatably installed on the base station and located in the groove, the rotating motor is fixed on the side wall of the stand, the output end of the rotating motor is connected with one end of the bearing shaft, the base station is fixed on the bearing shaft, and the die holder can be detachably connected to the base station.

Preferably, the protection component includes drive motor, transmission shaft, two carry on strip and two fixed plates, two the both sides at the pallet are installed respectively to the fixed plate, drive motor installs on a fixed plate and drive motor's output is connected with the one end of transmission shaft, the both ends of transmission shaft rotate with two fixed plates respectively and are connected, two carry on the strip and all fix on the transmission shaft.

Preferably, the transition conveying mechanism comprises a transition conveying belt, a linkage motor, a horizontal plate, a linkage plate and two L-shaped clamping arms, the horizontal plate is installed on one end side wall of the conveying roller machine, the linkage motor is fixed on the horizontal plate, the output end of the linkage motor is connected with the central portion of the linkage plate, the L-shaped clamping arms are symmetrically arranged on two sides of the supporting frame, one end of each L-shaped clamping arm is connected with one end of the linkage plate, and each L-shaped clamping arm slides with the supporting frame.

Preferably, turn-over mechanism includes left carrier assembly, right carrier assembly and two buffering subassemblies, left side carrier assembly and right carrier assembly all install on the support frame, two the buffering subassembly symmetry sets up on left carrier assembly, left side carrier assembly includes left grid grillage, left motor and first even axle, left side motor is installed on a lateral wall of support frame and the output of left motor is connected with the one end of first axle, the one end of left side grid grillage extends to the setting of transition conveyer belt, the other end and the first axle of left side grid grillage are connected.

Preferably, right side carrier assembly includes that right grid plate frame, right motor and second link axle, right side motor is installed on another lateral wall of support frame and the output of right motor is connected with the one end of second link axle, the one end of right side grid plate frame is connected with the second link axle, be equipped with two sucking discs on left side grid plate frame and the right grid plate frame.

Preferably, every the buffer unit all is including taking plate, arc and first spring, take the plate to fix the one end angle department at left grid grillage, arc and first spring all set up in the take the plate, just the both ends of first spring are connected with arc and take the plate respectively.

Preferably, the processing mechanism comprises two edging assemblies and two positioning assemblies, the two edging assemblies are symmetrically arranged on two sides of the support frame, the two positioning assemblies are symmetrically arranged on two sides of the support frame, each edging assembly comprises a first pushing cylinder, a first T-shaped plate, a fixed seat and a polishing roller, the first T-shaped plate is arranged on one side wall of the support frame, the first pushing cylinder is fixed on the first T-shaped plate, the output end of the first pushing cylinder is connected with the fixed seat, the polishing roller is rotatably arranged on the fixed seat, each positioning assembly comprises a second pushing cylinder, a second T-shaped plate, a push plate, a limiting plate and a plurality of second springs, the second T-shaped plate is arranged on one side wall of the support frame, the second pushing cylinder is fixed on the second T-shaped plate, and the output end of the second pushing cylinder is connected with the push plate, and the second springs are arranged between the push plate and the limiting plate at intervals, and two ends of each second spring are respectively connected with the push plate and the limiting plate.

The invention has the beneficial effects that:

1. the invention provides a glass injection molding die and a molding machine tool, wherein each raw material of glass is introduced into a material bearing cylinder, a rotating motor is used for driving a rotating shaft and a rotating blade to rotate, so that each raw material of the glass is fully mixed, then a motor is controlled for driving a fixed shaft and a rotating plate to rotate to open a material channel, so that the mixed raw material of the glass enters an injection cylinder body, a heater works to enable the raw material of the glass in the injection cylinder body to form liquid glass water, meanwhile, a screw rod sliding table drives a mounting bracket connected with a moving end of the screw rod sliding table and the injection cylinder body to move towards a molding mechanism, a screw rod and a helical blade are driven by a driving motor to rotate so that the liquid glass water is discharged from a discharge port of the injection cylinder body and falls into a concave die holder, an automatic feeding step before the glass injection molding is completed, after the liquid glass water is cooled for a period of time, a convex die holder on a movable die plate is driven by a lifting cylinder to move downwards to be pressed corresponding to the concave die holder, the automatic molding operation of glass injection molding and pressing is realized, the working efficiency is higher, and the mass production of glass can be met; .

2. According to the glass injection molding mold and the molding machine tool, after the automatic molding of glass injection molding and pressing is completed, the base station on the bearing shaft is driven to rotate through the rotating motor, the concave mold base on the base station is immediately driven to rotate synchronously, then the transmission motor drives the two carrying strips on the transmission shaft to rotate simultaneously, the molded glass in the concave mold base is synchronously supported, the condition that the molded glass is damaged in the process of falling to the conveying roller machine in a rotating and rotating mode is prevented, the production qualification rate of the glass is ensured, manual mold opening and blanking are not needed, the continuous injection molding of the glass is facilitated, and the integral production efficiency and quality are improved;

3. according to the glass injection molding die and the molding machine tool provided by the invention, after glass is conveyed to the conveying roller machine from the female die holder, the conveying roller machine conveys the glass to the transition conveying belt, the linkage motor is used for driving the linkage plate to rotate, and two L-shaped clamp arms connected with the linkage plate are driven to synchronously and relatively move, so that the limiting and correcting of two sides of the glass are realized, meanwhile, two first pushing cylinders are used for driving two grinding rollers on two fixed seats to synchronously and relatively move, so that the two grinding rollers are in contact with two sides of the glass, and the automatic edge grinding operation of two sides of the glass is realized under the conveying force action of the transition conveying belt; secondly, conveying the glass to the left grid plate frame by using the transition conveying belt, wherein the front end corner of the glass is limited by the arc plate, the condition that the front end corner of the glass is collided and damaged with the arc plate due to overlarge conveying force of the transition conveying belt can be prevented by using the first spring, the glass is adsorbed and positioned by using the two suckers arranged on the left grid plate frame, and finally, the existing glass processing equipment (such as an engraving machine, a cutting machine and the like) can be installed at the inner top of the installation cover plate, so that the automatic subsequent forming processing operation of the glass is realized;

4. the invention provides a glass injection molding mold and a molding machine tool, a left grid plate frame on a first connecting shaft is driven to rotate by a left motor, glass on the left grid plate frame is driven to rotate synchronously, meanwhile, a right motor drives a right grid plate frame on a second connecting shaft to rotate, when the left grid plate frame and the right grid plate frame are close to each other, the sucker on the right grid plate frame works to suck the other side of the glass, the sucker on the left grid plate frame stops working, thereby completing the turnover and transfer of the glass from the left grid plate frame to the right grid plate frame, further improving the practicability of the whole equipment, meeting the double-sided processing and forming requirements of the glass, wherein, utilize two second to promote two push pedals of cylinder drive and two limiting plate relative movement, realize the location operation before the glass processing, the second spring can cushion the tight buffer power of clamp before the glass location, prevents that the condition of glass from appearing pressing from both sides the damage and takes place.

Drawings

FIG. 1 is a first perspective view of the present invention;

FIG. 2 is a schematic perspective view of the present invention;

FIG. 3 is a top view of the present invention;

FIG. 4 is a schematic perspective view of the feeding mechanism of the present invention;

FIG. 5 is a cross-sectional view of the invention of FIG. 4;

FIG. 6 is a schematic perspective view of a molding mechanism according to the present invention;

FIG. 7 is a cross-sectional view of the invention of FIG. 6;

FIG. 8 is a partial perspective view of the present invention;

FIG. 9 is a top view of the present invention of FIG. 8;

FIG. 10 is a cross-sectional view of the invention of FIG. 8;

fig. 11 is an enlarged view of the invention at B in fig. 9.

Reference numerals:

a feeding mechanism 1, a bearing table 11, a screw rod sliding table 12, a mounting bracket 13, a mixing component 14, a material bearing cylinder 141, a rotating motor 142, a rotating shaft 143, a rotating blade 144, a bottom table 145, a control motor 146, a rotating plate 147, an injection molding cylinder 15, a driving motor 16, a screw 17, a spiral blade 18, a molding mechanism 2, a stand 21, a rotating module 22, a rotating motor 221, a bearing shaft 222, a base table 223, a female die holder 224, a protective component 23, a transmission motor 231, a transmission shaft 232, a carrying bar 233, a fixed plate 234, a movable die plate 24, a mounting plate 25, a lifting cylinder 26, a guide post 27, a male die holder 28, a conveying roller machine 3, a transition conveying mechanism 4, a transition conveying belt 41, a linkage motor 42, a horizontal plate 43, a linkage plate 44, an L-shaped clamping arm 45, a support frame 5, a turn-over mechanism 6, a left bearing component 61, a left grid plate frame 611, a left motor 612, a first connecting shaft 613, a right bearing component 62, the device comprises a right grid plate frame 621, a right motor 622, a second connecting shaft 623, a buffering component 63, a lapping plate 631, an arc-shaped plate 632, a first spring 633, a sucking disc 64, a processing mechanism 7, an edging component 71, a first pushing cylinder 711, a first T-shaped plate 712, a fixing seat 713, a polishing roller 714, a positioning component 72, a second pushing cylinder 721, a second T-shaped plate 722, a pushing plate 723, a limiting plate 724, a second spring 725 and an installation cover plate 8.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1-11, the invention provides a glass injection molding mold and a molding machine tool, comprising a feeding mechanism 1, a molding mechanism 2, a conveying roller machine 3, a transition conveying mechanism 4, a support frame 5, a turn-over mechanism 6 and a processing mechanism 7, wherein the feeding mechanism 1 is arranged at one side of the molding mechanism 2, the molding mechanism 2 is transversely arranged at the feeding end of the conveying roller machine 3, the transition conveying mechanism 4 is arranged at the discharging end of the conveying roller machine 3, one end of the support frame 5 is connected with the discharging end of the conveying roller machine 3, the turn-over mechanism 6 is arranged on the support frame 5, the processing mechanism 7 is arranged at the top of the support frame 5, mounting cover plates 8 are arranged on the upper covers of the conveying roller machine 3 and the support frame 5, the feeding mechanism 1 comprises a bearing platform 11, a screw rod sliding table 12, a mounting bracket 13, a mixing component 14 and an injection molding cylinder 15, the bearing platform 11 is transversely arranged at one side of the molding mechanism 2, lead screw slip table 12 is installed at the interior top of plummer 11, the bottom of installing support 13 is connected with the removal end of lead screw slip table 12, the barrel 15 of moulding plastics is fixed on installing support 13, be equipped with driving motor 16 on the installing support 13, be equipped with heater, screw rod 17 and helical blade 18 in the barrel 15 of moulding plastics, driving motor 16's output is connected with the one end of screw rod 17 through the shaft coupling, helical blade 18 is fixed on screw rod 17.

The specific working process is as follows: the glass raw materials are introduced into a material bearing barrel 141, a rotating shaft 143 and a rotating blade 144 are driven to rotate by a rotating motor 142, so that the glass raw materials are fully mixed, then a motor 146 is controlled to drive a fixed shaft and a rotating plate 147 to rotate to open a material channel, so that the mixed glass raw materials enter an injection cylinder 15, a heater works to enable the glass raw materials in the injection cylinder 15 to form liquid glass water, meanwhile, a screw rod sliding table 12 drives a mounting bracket 13 connected with the moving end of the screw rod sliding table and the injection cylinder 15 to move towards a forming mechanism 2, a driving motor 16 drives a screw rod 17 and a spiral blade 18 to rotate so that the liquid glass water is discharged from a discharge port of the injection cylinder 15 and falls into a concave die holder 224, an automatic feeding step before glass injection is completed, after the liquid glass water is cooled for a period of time, a convex die holder 28 on a movable die plate 24 is driven to move downwards to be pressed corresponding to the concave die holder 224 by a lifting cylinder 26, the automatic molding operation of glass injection molding and pressing is realized, the working efficiency is higher, and the mass production of glass can be met; after the automatic molding of the glass by injection molding and pressing is finished, the base 223 on the bearing shaft 222 is driven to rotate by the rotating motor 221, the female die holder 224 on the base 223 is immediately driven to rotate synchronously, then the transmission motor 231 drives the two carrying strips 233 on the transmission shaft 232 to rotate simultaneously, and the molded glass in the female die holder 224 is synchronously supported, so that the condition that the molded glass is damaged in the process of rotating, rotating and falling to the conveying roller machine 3 is prevented, the production qualification rate of the glass is ensured, manual die sinking and blanking are not needed, the continuous injection molding of the glass is facilitated, and the integral production efficiency and quality are improved; after glass is conveyed to the conveying roller machine 3 from the interior of the concave die holder 224, the conveying roller machine 3 conveys the glass to the transition conveying belt 41, the linkage plate 44 is driven to rotate by the linkage motor 42, the two L-shaped clamping arms 45 connected with the linkage plate 44 are driven to synchronously and relatively move, the limiting and correcting of two sides of the glass are realized, meanwhile, the two grinding rollers 714 on the two fixing seats 713 are driven to synchronously and relatively move by the two first pushing cylinders 711, the two grinding rollers 714 are in contact with two sides of the glass, and the automatic edge grinding operation of the two sides of the glass is realized under the conveying force action of the transition conveying belt 41; secondly, the glass is conveyed to the left grid plate frame 611 by the transition conveying belt 41, wherein the front end corner of the glass is limited by the arc-shaped plate 632, the situation that the front end corner of the glass is collided and damaged with the arc-shaped plate 632 due to overlarge conveying force of the transition conveying belt 41 can be prevented by the first spring 633, the glass is adsorbed and positioned by the two suckers 64 arranged on the left grid plate frame 611, and finally, the existing glass processing equipment such as a carving machine, a cutting machine and the like can be installed at the inner top of the installation cover plate 8, so that automatic subsequent forming processing operation of the glass is realized; the left grid plate frame 611 on the first connecting shaft 613 is driven to rotate by the left motor 612, glass on the left grid plate frame 611 is driven to rotate synchronously, meanwhile, the right motor 622 drives the right grid plate frame 621 on the second connecting shaft 623 to rotate, when the left grid plate frame 611 is close to the right grid plate frame 621, the sucking disc 64 on the right grid plate frame 621 works to suck the other side of the glass, and the sucking disc 64 on the left grid plate frame 611 stops working, so that the glass is turned over and conveyed to the right grid plate frame 621 from the left grid plate frame 611, the practicability of the whole equipment is further improved, the requirement of double-sided processing and forming of the glass is met, wherein the two second pushing cylinders 721 are used for driving the two pushing plates 723 and the two limiting plates 724 to move relatively, the positioning operation before the glass processing is realized, the second springs 725 can buffer the clamping buffer force before the glass positioning, and the glass is prevented from being damaged.

In one embodiment, the mixing assembly 14 includes a material receiving barrel 141, a rotating motor 142, a rotating shaft 143, a rotating blade 144, a bottom platform 145, a control motor 146, a rotating plate 147 and a fixed shaft, the bottom platform 145 is fixed on the injection molding barrel body 15, the material receiving barrel 141 is fixed on the bottom platform 145, the rotating shaft 143 is rotatably installed in the material receiving barrel 141, the rotating motor 142 is fixed on the top of the material receiving barrel 141, the output end of the rotating motor 142 is connected with the top end of the rotating shaft 143, the rotating blade 144 is fixed on the rotating shaft 143, a material channel connected with the material receiving barrel 141 and the injection molding barrel body 15 is arranged on the bottom platform 145, the fixed shaft is rotatably arranged in the material channel, the rotating plate 147 is fixed on the fixed shaft, the control motor 146 is installed on the outer side wall of the bottom platform 145, and the output end of the control motor 146 is connected with one end of the fixed shaft.

The glass raw materials are introduced into the material bearing barrel 141, the rotating motor 142 is used for driving the rotating shaft 143 and the rotating blades 144 to rotate, so that the glass raw materials are fully mixed, then the motor 146 is controlled to drive the fixed shaft and the rotating plate 147 to rotate to open a material channel, so that the mixed glass raw materials enter the injection molding barrel 15, the heater works to enable the glass raw materials in the injection molding barrel 15 to form liquid glass water, meanwhile, the lead screw sliding table 12 drives the mounting support 13 connected with the moving end of the lead screw sliding table and the injection molding barrel 15 to move towards the forming mechanism 2, and the driving motor 16 drives the screw 17 and the helical blades 18 to rotate so that the liquid glass water is discharged from the discharge port of the injection molding barrel 15 and falls into the concave die holder 224, and the automatic feeding step before glass injection molding is completed.

In one embodiment, the forming mechanism 2 includes a stand 21, a rotating module 22, a protection component 23, a movable mold plate 24, a mounting plate 25, a lifting cylinder 26, and four guide posts 27, the stand 21 is transversely disposed at a feeding end of the conveyor roller 3, the rotating module 22 is mounted at a top of the stand 21, the protection component 23 is mounted on an inner side wall of the stand 21, the four guide posts 27 are vertically mounted on the top of the stand 21 in a rectangular shape, the mounting plate 25 is fixed on top ends of the four guide posts 27, the lifting cylinder 26 is fixed on top of the mounting plate 25, the movable mold plate 24 is slidably disposed on the four guide posts 27, and a male mold seat 28 detachably connected to the bottom of the movable mold plate 24 is disposed at the bottom of the movable mold plate 24.

When the mounting bracket 13 and the injection cylinder 15 connected with the moving ends of the screw rod sliding table 12 are driven to move towards the rotating module 22 by the screw rod sliding table 12, the driving motor 16 drives the screw rod 17 and the helical blade 18 to rotate so that liquid glass water is discharged from a discharge port of the injection cylinder 15 and falls into the concave die holder 224, and an automatic feeding step before glass injection is completed; the disassembly and assembly of the female die holder 224 and the male die holder 28 can meet the requirements of glass forming steps of different sizes, and the automatic blanking operation of the formed glass can be realized by the rotating module 22 and the protective assembly 23.

In one embodiment, the rotating die holder includes a rotating motor 221, a bearing shaft 222, a base 223 and a die holder 224, a groove for the base 223 to rotate is formed in the stand 21, the bearing shaft 222 is rotatably installed on the base 223 and located in the groove, the rotating motor 221 is fixed on a side wall of the stand 21, an output end of the rotating motor 221 is connected with one end of the bearing shaft 222, the base 223 is fixed on the bearing shaft 222, and the die holder 224 is detachably connected to the base 223.

After the automatic molding of glass injection molding and pressing is completed, the base station 223 on the bearing shaft 222 is driven to rotate by the rotating motor 221, the female die holder 224 on the base station 223 is immediately driven to rotate synchronously, then the protective assembly 23 works to synchronously support the molded glass in the female die holder 224, the condition that the molded glass is damaged due to the fact that the molded glass rotates and falls to the conveying roller machine 3 is prevented, the production qualification rate of the glass is ensured, manual die opening and blanking are not needed, the continuous injection molding of the glass is facilitated, and the overall production efficiency and quality are improved.

In one embodiment, the protection assembly 23 includes a transmission motor 231, a transmission shaft 232, two carrying bars 233 and two fixing plates 234, the two fixing plates 234 are respectively installed at two sides of the stand 21, the transmission motor 231 is installed on one fixing plate 234, an output end of the transmission motor 231 is connected to one end of the transmission shaft 232, two ends of the transmission shaft 232 are respectively rotatably connected to the two fixing plates 234, and the two carrying bars 233 are both fixed to the transmission shaft 232.

Two carrying strips 233 on the driving shaft 232 are driven to rotate simultaneously through the driving motor 231, formed glass in the die holder 224 is synchronously supported, the formed glass is prevented from being damaged in the process of rotating, rotating and falling to the conveying roller 3, and the production qualified rate of the glass is ensured.

In one embodiment, the transition conveying mechanism 4 includes a transition conveying belt 41, a linkage motor 42, a horizontal plate 43, a linkage plate 44 and two L-shaped clamping arms 45, the horizontal plate 43 is installed on a side wall of one end of the conveying roller 3, the linkage motor 42 is fixed on the horizontal plate 43, an output end of the linkage motor 42 is connected with a central portion of the linkage plate 44, the two L-shaped clamping arms 45 are symmetrically arranged on two sides of the supporting frame 5, one end of each L-shaped clamping arm 45 is connected with one end of the linkage plate 44, and each L-shaped clamping arm 45 slides with the supporting frame 5.

After the glass is transferred to the conveying roller machine 3 from the die holder 224, the conveying roller machine 3 conveys the glass to the transition conveying belt 41, the linkage plate 44 is driven to rotate by the linkage motor 42, the two L-shaped clamping arms 45 connected with the linkage plate 44 are driven to synchronously and relatively move, the limiting and righting of the two sides of the glass are realized, and meanwhile, the automatic edge grinding operation of the two sides of the glass can be realized under the cooperation of the conveying force effect of the transition conveying belt 41 and the processing mechanism 7.

In one embodiment, the turnover mechanism 6 includes a left bearing assembly 61, a right bearing assembly 62 and two buffering assemblies 63, the left bearing assembly 61 and the right bearing assembly 62 are both installed on the supporting frame 5, two buffering assemblies 63 are symmetrically disposed on the left bearing assembly 61, the left bearing assembly 61 includes a left grid plate rack 611, a left motor 612 and a first connecting shaft 613, the left motor 612 is installed on one side wall of the supporting frame 5, an output end of the left motor 612 is connected with one end of the first connecting shaft 613, one end of the left grid plate rack extends to the arrangement of the transition conveying belt 41, and the other end of the left grid plate rack 611 is connected with the first connecting shaft 613.

The glass is conveyed to the left grid plate frame 611 by the transition conveying belt 41, wherein the two buffer assemblies 63 can prevent the front end corner of the glass from being damaged due to overlarge conveying force of the transition conveying belt 41, the glass is adsorbed and positioned by the two suckers 64 arranged on the left grid plate frame 611, and finally, the existing glass processing equipment such as a carving machine, a cutting machine and the like can be installed at the inner top of the installation cover plate 8, so that the automatic subsequent forming processing operation of the glass is realized; the left grid plate frame 611 on the first connecting shaft 613 is driven to rotate by the left motor 612, so that the glass on the left grid plate frame 611 is driven to rotate synchronously, and meanwhile, the right bearing assembly 62 finishes the operation of transferring the glass from the upside-down side of the left grid plate frame 611 to the right bearing assembly 62, so that the practicability of the whole equipment is further improved, and the requirement of double-sided processing and forming of the glass is met.

In one embodiment, the right bearing assembly 62 includes a right grid plate frame 621, a right motor 622 and a second connecting shaft 623, the right motor 622 is installed on the other side wall of the supporting frame 5, and the output end of the right motor 622 is connected with one end of the second connecting shaft 623, one end of the right grid plate frame 621 is connected with the second connecting shaft 623, and two suckers 64 are disposed on the left grid plate frame 611 and the right grid plate frame 621.

The transition conveyor belt 41 is used for conveying the glass to the left grid plate frame 611, the two suckers 64 arranged on the left grid plate frame 611 are used for adsorbing and positioning the glass, and the existing glass processing equipment such as a carving machine, a cutting machine and the like can be arranged at the inner top of the mounting cover plate 8, so that the automatic subsequent forming processing operation of the glass is realized; through the rotation of left grid plate rack 611 on left motor 612 drive first connecting shaft 613, drive the synchronous rotation of glass on the left grid plate rack 611, meanwhile, right grid plate rack 621 on the second connecting shaft 623 of right motor 622 drive rotates, when left grid plate rack 611 is close to with right grid plate rack 621, the work of sucking disc 64 on the right grid plate rack 621 adsorbs the glass another side, sucking disc 64 stop work on the left grid plate rack 611, thereby accomplish glass and transfer to right grid plate rack 621 from left grid plate rack 611 turn-over, the practicality of whole equipment has further been improved, satisfy glass's two-sided machine-shaping demand.

In one embodiment, each of the buffer assemblies 63 includes a board 631, an arc-shaped board 632, and a first spring 633, the board 631 is fixed at one end of the left grid board rack 611, the arc-shaped board 632 and the first spring 633 are both disposed in the board 631, and two ends of the first spring 633 are respectively connected to the arc-shaped board 632 and the board 631.

Carry glass to left grid frame 611 through transition conveyer belt 41 on, wherein arc 632 carries on spacingly to glass's front end angle, can prevent through first spring 633 that the conveying power of transition conveyer belt 41 is too big to cause the glass front end angle to contradict the condition emergence of damage with arc 632.

In one embodiment, the processing mechanism 7 includes two edging assemblies 71 and two positioning assemblies 72, the two edging assemblies 71 are symmetrically installed on two sides of the supporting frame 5, the two positioning assemblies 72 are symmetrically installed on two sides of the supporting frame 5, each edging assembly 71 includes a first pushing cylinder 711, a first T-shaped plate 712, a fixing seat 713 and a grinding roller 714, the first T-shaped plate 712 is installed on one side wall of the supporting frame 5, the first pushing cylinder 711 is fixed on the first T-shaped plate 712, an output end of the first pushing cylinder 711 is connected with the fixing seat 713, the grinding roller 714 is rotatably installed on the fixing seat 713, each positioning assembly 72 includes a second pushing cylinder 721, a second T-shaped plate 722, a push plate 723, a limit plate 724 and a plurality of second springs 725, the second T-shaped plate 722 is installed on one side wall of the supporting frame 5, the second pushing cylinders 721 are fixed on the second T-shaped plate 722, the output ends of the second pushing cylinders 721 are connected with the push plate 723, the second springs 725 are arranged between the push plate 723 and the limiting plate 724 at intervals, two ends of each second spring 725 are respectively connected with the push plate 723 and the limiting plate 724, the two first pushing cylinders 711 are used for driving the two grinding rollers 714 on the two fixing seats 713 to synchronously and relatively move, the two grinding rollers 714 are in contact with two sides of glass, and automatic edge grinding operation on two sides of the glass is realized under the conveying force action of the transition conveying belt 41; after the glass is turned over and transferred to the right grid plate 621 from the left grid plate 611, the two second pushing cylinders 721 are used for driving the two pushing plates 723 and the two limiting plates 724 to move relatively, the positioning operation before the glass processing is achieved, the second springs 725 can buffer the clamping buffering force before the glass is positioned, and the glass is prevented from being damaged due to clamping.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

The electrical components presented in the document are all electrically connected with an external master controller and 220V mains, and the master controller can be a conventional known device controlled by a computer or the like.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.