CN218429918U - Plastic uptake production line - Google Patents

Abstract

The application discloses blister production line includes: the plastic suction machine comprises an upper die module and a lower die module which are arranged up and down correspondingly, the upper die module comprises a first driving assembly and an upper die base, the first driving assembly is driven to be connected with the upper die base, the bottom of the upper die base is used for being connected with an upper die, the lower die module comprises a second driving assembly and a lower die base, the second driving assembly is driven to be connected with the lower die base, the top of the lower die base is used for being connected with a lower die, the upper die or the lower die is provided with an air suction hole, and the upper die or the lower die is communicated with the negative pressure generating device through the air suction hole; the first conveyor penetrates through the space between the upper die module and the lower die module and is used for conveying materials, and an avoiding position is formed in the middle of the first conveyor so that the plastic uptake machine can carry out plastic uptake forming on the materials through the avoiding position. The plastic uptake production line can improve plastic uptake molding efficiency.

Description

Plastic uptake production line

Technical Field

The application relates to the technical field of plastic uptake, in particular to a plastic uptake production line.

Background

In the related art, a common plastic sucking machine in the market generally arranges an upper die to be movable along a guide rail, a dragging die which runs continuously is arranged on a table surface corresponding to the upper die, and a plurality of groups of lower dies corresponding to the upper die are arranged on the dragging die along the running direction. After the thin sheet product is extruded by the extruder, the upper die and one group of lower dies are matched for forming, the upper die and the lower dies move along the guide rail and gradually approach the cutting machine, after the product is formed and conveyed to the cutting machine, the upper die returns to the original position, the next forming procedure is continuously carried out with the other group of lower dies, and the circular processing is carried out. However, in the process of returning to the original position after the upper mold is formed, the forming operation is stopped, so that the forming efficiency of the plastic uptake machine is required to be improved.

SUMMERY OF THE UTILITY MODEL

The utility model discloses aim at solving one of the technical problem that exists among the prior art at least. For this reason, this application provides a plastic uptake production line, can improve plastic uptake shaping efficiency.

According to the utility model discloses a plastic uptake production line of first aspect embodiment, include: the plastic suction machine comprises an upper die module and a lower die module which are arranged up and down correspondingly, the upper die module comprises a first driving assembly and an upper die base, the first driving assembly is used for driving the upper die base to lift, the bottom of the upper die base is used for being connected with an upper die, the lower die module comprises a second driving assembly and a lower die base, the second driving assembly is used for driving the lower die base to lift, the top of the lower die base is used for being connected with a lower die, the upper die or the lower die is provided with an air suction hole, and the upper die or the lower die is communicated with a negative pressure generating device through the air suction hole; the first conveyor penetrates through the upper die module and the lower die module and is used for conveying materials, an avoiding position is formed in the middle of the first conveyor, and the avoiding position allows the upper die and the lower die to penetrate through and be matched with the die.

According to the utility model discloses plastic uptake production line has following beneficial effect at least: the plastic uptake production line comprises a plastic uptake machine and a first conveyor, wherein the plastic uptake machine comprises an upper die module and a lower die module which are arranged from top to bottom and are arranged correspondingly, the upper die module comprises a first driving component, an upper die base and an upper die, the bottom of the upper die base is connected with the upper die, the upper die base can drive the upper die to lift under the driving of the first driving component, the lower die module comprises a second driving component, a lower die base and a lower die, the top of the lower die base is connected with the lower die, the lower die base can drive the lower die to lift under the driving of the second driving component, so that the upper die and the lower die can approach each other and are closed, and the upper die or the lower die is provided with an air suction hole, so that the material is subjected to plastic uptake forming; simultaneously, wear to be equipped with first conveyer between last mould module and lower mould module, first conveyer middle part is formed with the position of dodging, thereby when the material that carries to the plastic uptake machine through first conveyer, the material passes between last mould module and the lower mould module, first conveyer stops a little, it moulds the material plastic uptake shaping to dodge a position matched mold to go up mould and lower mould, first conveyer continues to carry the material afterwards, go up mould and lower mould matched mold shaping once more, thereby under the transport of first conveyer, make and go up mould and lower mould and no longer do the removal of horizontal direction, and only need the matched mold die, thereby the shaping efficiency of this kind of plastic uptake production line has been improved greatly.

According to some embodiments of the invention, the first conveyor comprises two sets of conveyor belt mechanisms, the dodging position is formed between the two sets of conveyor belt mechanisms.

According to the utility model discloses a some embodiments, the aspirating hole that is used for intercommunication negative pressure to produce the device is offered to the lower mould, go up the mould and offer the inlet port that is used for communicateing air compressor.

According to the utility model discloses a some embodiments, go up the mould in with be equipped with the cooling water course of taking the mouth of a river and delivery port in the lower mould.

According to some embodiments of the utility model, the front side of plastic uptake machine is equipped with the extruder, the extruder is used for melting the back court with the former material of plastics the direction of first conveyer is extruded.

According to the utility model discloses a some embodiments, be equipped with the roller press on the ejection of compact direction of extruder, the roller press is located the plastic uptake machine front side, the roller press is used for rolling the strip material of the plastics roller extrusion into required thickness.

According to some embodiments of the utility model, follow the transport route of first conveyer is equipped with and is located the guillootine of plastic uptake machine rear side, the guillootine can pass through keep away the position after to the shaping the material cuts.

According to some embodiments of the utility model, still include elevating gear, elevating gear locates the plastic uptake machine with between the guillootine, elevating gear is used for lifting the mould and send to the die holding area of plastic uptake machine, and/or is used for the cutting board of guillootine is lifted and is sent to the cutting board mounting area of guillootine, the mould includes go up the mould with the lower mould.

According to some embodiments of the utility model, follow the transport route of first conveyer is equipped with and is located the pile mechanism of guillootine rear side, pile mechanism can be with being located avoid the position the material is ejecting and stacking together.

According to some embodiments of the utility model, follow the output direction of first conveyer is equipped with and is located the rolling machine of stacker rear side, the rolling machine is used for the waste material rolling.

Additional aspects and advantages of the present application will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the present application.

Drawings

The invention will be further described with reference to the following drawings and examples, in which:

fig. 1 is a schematic overall structure diagram of an embodiment of the present invention;

fig. 2 is a schematic structural diagram of a first conveyor according to an embodiment of the present invention;

FIG. 3 is a schematic structural view of a vacuum forming machine according to an embodiment of the present invention;

fig. 4 is a schematic structural view of a roller press according to an embodiment of the present invention;

fig. 5 is a schematic structural view of a cutting machine and a lifting device in the embodiment of the present invention;

FIG. 6 is an enlarged view of a portion of FIG. 5 at A;

fig. 7 is a schematic structural diagram of a stacking assembly according to an embodiment of the present invention.

Reference numerals are as follows:

100. a plastic sucking machine; 110. an upper die module; 111. a first drive assembly; 112. an upper die holder; 120. a lower die module; 121. a second drive assembly; 122. a lower die holder;

200. a first conveyor; 210. a conveyor belt mechanism; 211. a third driving member; 212. a conveyor belt; 213. a pulley; 220. avoidance positions; 230. a drive shaft;

300. an extruder;

400. a roll squeezer; 410. a first press roll; 420. a second press roll; 430. a third press roll; 440. a mounting frame; 450. a fourth drive;

500. a mold temperature controller;

600. a lifting device; 610. a sliding table; 620. a linear module; 630. a mounting seat; 640. a lifting platform; 641. a fixed seat; 642. rolling a ball;

700. a cutting machine; 710. an upper die unit; 720. a lower die unit;

800. a stacking mechanism; 810. a linear module; 820. a connecting frame; 830. a suction nozzle;

900. a winding machine;

1000. a frame; 1100. and (4) a linear sliding table.

Detailed Description

Reference will now be made in detail to embodiments of the present application, examples of which are illustrated in the accompanying drawings, wherein like or similar 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 the accompanying drawings are illustrative and are only for the purpose of explaining the present application and are not to be construed as limiting the present application.

In the description of the present application, it is to be understood that the positional descriptions, such as the directions of up, down, front, rear, left, right, etc., referred to herein are based on the directions or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, and do not indicate or imply that the referred device or element must have a specific direction, be constructed and operated in a specific direction, and thus, should not be construed as limiting the present application.

In the description of the present application, the meaning of a plurality is one or more, the meaning of a plurality is two or more, and the above, below, exceeding, etc. are understood as excluding the present number, and the above, below, within, etc. are understood as including the present number. If the first and second are described for the purpose of distinguishing technical features, they are not to be understood as indicating or implying relative importance or implicitly indicating the number of technical features indicated or implicitly indicating the precedence of the technical features indicated.

In the description of the present application, unless otherwise expressly limited, terms such as set, mounted, connected and the like should be construed broadly, and those skilled in the art can reasonably determine the specific meaning of the terms in the present application by combining the detailed contents of the technical solutions.

In the description of the present application, reference to the description of the terms "one embodiment," "some embodiments," "an illustrative embodiment," "an example," "a specific example," or "some examples," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present application. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The plastic uptake production line according to an embodiment of the present invention is described below with reference to fig. 1 to 7.

As shown in figures 1 to 3, according to the utility model discloses a plastic uptake production line includes: the plastic suction machine 100 comprises an upper die module 110 and a lower die module 120 which are arranged up and down correspondingly, the upper die module 110 comprises a first driving assembly 111 and an upper die base 112, the first driving assembly 111 is used for driving the upper die base 112 to ascend and descend, the bottom of the upper die base 112 is used for connecting an upper die, the lower die module 120 comprises a second driving assembly 121 and a lower die base 122, the second driving assembly 121 is used for driving the lower die base 122 to ascend and descend, the top of the lower die base 122 is used for connecting a lower die, the upper die or the lower die is provided with an air suction hole, and the upper die or the lower die is communicated with a negative pressure generating device through the air suction hole; the first conveyor 200 is inserted between the upper mold module 110 and the lower mold module 120 and used for conveying materials, and an avoiding position 220 is formed in the middle of the first conveyor 200, and the avoiding position 220 allows the upper mold and the lower mold to pass through and be closed.

It can be understood that the plastic uptake production line comprises a plastic uptake machine 100 and a first conveyor 200, the plastic uptake machine 100 comprises an upper die module 110 and a lower die module 120 which are arranged from top to bottom and correspondingly, the upper die module 110 comprises a first driving component 111, an upper die base 112 and an upper die, the bottom of the upper die base 112 is connected with the upper die, the upper die base 112 can drive the upper die to lift under the driving of the first driving component 111, the lower die module 120 comprises a second driving component 121, a lower die base 122 and a lower die, the top of the lower die base 122 is connected with the lower die, and the lower die base 122 can drive the lower die to lift under the driving of the second driving component 121, so that the upper die and the lower die can approach each other and are matched, and the upper die or the lower die is provided with an air suction hole, so as to carry out plastic uptake molding on materials; meanwhile, a first conveyor 200 is arranged between the upper mold module 110 and the lower mold module 120 in a penetrating manner, and an avoidance position 220 is formed in the middle of the first conveyor 200, so that when materials are conveyed to the plastic uptake machine 100 through the first conveyor 200, the materials pass through the space between the upper mold module 110 and the lower mold module 120, the first conveyor 200 stops slightly, the upper mold and the lower mold are closed at the avoidance position 220 to carry out plastic uptake molding on the materials, then the first conveyor 200 continues to convey the materials, the upper mold and the lower mold are closed again for molding, so that the upper mold and the lower mold do not move in the horizontal direction any more under the conveying of the first conveyor 200, and only the mold is opened, so that the molding efficiency of the plastic uptake production line is greatly improved; simultaneously the lower mould in the plastic uptake production line in this application only sets up one department and can realize the plastic uptake, and need not set up one row of lower mould along the transfer chain to greatly reduced the cost of mould.

The specific setting mode of the equipment manufacturer is different according to different customer needs. For example, in this embodiment, the lower mold is a female mold, so that an air exhaust hole is formed in the lower mold, and the lower mold is connected to the negative pressure generating device through the air exhaust hole, so that a cavity with negative pressure is formed in the lower mold, and thus, a product is formed in the lower mold by vacuum forming. In other embodiments, when the upper mold is a female mold, the upper mold may also be provided with an air exhaust hole, and the upper mold is connected to the negative pressure generating device through the air exhaust hole, so that the upper mold forms a cavity with negative pressure, and thus, a product is formed in the upper mold through vacuum forming.

It will be appreciated that the first conveyor 200 includes two sets of conveyor belt 212 mechanisms 210, with the escape position 220 being formed between the two sets of conveyor belt 212 mechanisms 210. For example, as shown in fig. 2, in the present embodiment, the first conveyor 200 includes two sets of conveyor belt 212 mechanisms 210, each conveyor belt 212 mechanism 210 includes a conveyor belt 212 and at least two pulleys 213, at least two pulleys 213 are drivingly connected by the conveyor belt 212, and the avoidance position 220 is formed between the two sets of conveyor belt 212 mechanisms 210.

It should be understood that in the embodiment of the present application, one pulley 213 of one set of the conveyor belt 212 mechanisms 210 is driven to rotate by the third driving member 211, and one pulley 213 of one set of the conveyor belt 212 mechanisms 210 drives one pulley 213 of the other set of the conveyor belt 212 mechanisms 210 to rotate by the transmission shaft 230, so that one set of the conveyor belt 212 mechanisms 210 drives the other set of the conveyor belt 212 mechanisms 210 to rotate. In other embodiments, two sets of the conveyor belt 212 mechanisms 210 may be respectively provided with one third driving member 211 to drive the conveyor belt 212 mechanisms 210 of each set to transmit, but the two third driving members 211 need to be set in a manner that the rotation speed and the start and stop are in step, so as to transport the material.

It should be understood that the conveyor belt 212 of the conveyor belt 212 mechanism 210 may be replaced by a chain or the like, as long as one side of the product can be supported and transported.

It can be understood that the lower die is provided with an air exhaust hole for communicating with the negative pressure generating device, and the upper die is provided with an air inlet hole for communicating with the air compressor. For example, in the present embodiment, the air exhaust hole is opened in the lower mold, so the lower mold is connected to the negative pressure generating device, and the lower mold can generate negative pressure; meanwhile, the upper die is provided with an air inlet hole and is connected with an air compressor through the air inlet hole, so that positive pressure is generated on the upper die, and the molding effect of the matched die of the upper die and the lower die on materials is improved under the combined action of the positive pressure and the negative pressure.

It can be understood that cooling water channels with water inlets and water outlets are arranged in the upper die and the lower die. For example, in the present embodiment, since the material is in a high temperature state during the process of closing and molding the upper mold and the lower mold, the temperature of the upper mold and the lower mold is increased after receiving heat, but the long-term high temperature easily affects the service life of the upper mold and the lower mold. Meanwhile, the cooled die is in the die assembly forming process, so that the forming effect of the product is improved, the product is easy to solidify, and the subsequent cutting of the formed product is facilitated. Therefore, cooling water channels are arranged in the upper die and the lower die, and the cooling of the die is realized by injecting cold water into the upper die and the lower die. The upper die and the lower die are provided with a water inlet and a water outlet, so that the circulating water cooling device is convenient to connect, cold water is taken away from the water inlet through a cooling water channel after entering, the cold water is changed into hot water when flowing out of the water outlet, the hot water is changed into cold water after being cooled by the circulating water cooling device, and the cold water enters the die from the water inlet, so that the purpose of recycling is achieved.

It should be understood that a plurality of vertical first guide posts are provided between the upper die base 112 and the lower die base 122, so as to ensure that the upper die base 112 and the lower die base 122 can move linearly in the vertical direction.

It is understood that the front side of the suction molding machine 100 is provided with an extruder 300, and the extruder 300 is used for melting and extruding the plastic log in the direction of the first conveyor 200. For example, as shown in fig. 1, in the present embodiment, an extruder 300 is provided at the front side of the vacuum molding machine 100, and the plastic log is melted by plasticization of the extruder 300 and then extruded, so that the material can be continuously fed to the first conveyor 200.

It should be understood that, in the blister production line of the present application, the extruder 300 may continuously extrude the molten material, and the first conveyor 200 temporarily stops conveying the strip-shaped material extruded by the extruder 300 during the 2-3 seconds of the mold closing and forming stop of the blister 100, and when the mold is opened after the blister 100 is formed, the first conveyor 200 starts conveying the material, and the drooped material is moved onto the first conveyor 200 while the formed material is moved out of the blister 100 for the next processing of the blister 100.

It is understood that a roller press 400 is provided in the discharging direction of the extruder 300, the roller press 400 is located at the front side of the blister machine 100, and the roller press 400 is used for rolling the extruded plastic into a belt-shaped material with a desired thickness. For example, as shown in fig. 1 and 4, in the present embodiment, a roller press 400 is provided between the extruder 300 and the blister 100, and the roller press 400 is used for rolling the molten plastic extruded from the extruder 300 into a strip-shaped material with a certain thickness.

It should be understood that the roller press 400 includes at least two rollers arranged in parallel, and the plastic material in a molten state is rolled into a strip-shaped material with a certain thickness after passing through a gap between the rollers. The gap between the rolls can be adjusted according to the thickness required. In this embodiment, the roll press includes a first press roll 410, a second press roll 420 and a third press roll 430 which are sequentially arranged in parallel, and a gap between the first press roll 410 and the second press roll 420 is different from a gap between the second press roll 420 and the third press roll 430, so that materials with different thicknesses can be rolled out. Specifically, three press rollers are arranged on the mounting frame 440 and are driven to press by a fourth driving member 450, pulleys 213 are arranged on the outer sides of the three press rollers, the fourth driving member 450 drives one of the pulleys 213 to rotate, and the three pulleys 213 are in transmission connection through a chain.

It should be understood that, according to the environment or specific requirements, a mold temperature controller 500 may be further disposed between the roller press 400 and the plastic uptake machine 100 to prevent the temperature from being too low, or the material is cooled after passing through the roller press 400, so as to affect the plastic uptake molding effect of the material. Can guarantee through mould temperature machine 500 that the material keeps in the high temperature state when getting into the plastic uptake machine, improve the fashioned effect of material plastic uptake.

It is understood that a cutter 700 is provided along the conveying path of the first conveyor 200 at the rear side of the blister 100, and the cutter 700 can cut the formed material through the escape position 220. For example, as shown in fig. 1 and 5, in the present embodiment, the blister device further includes a cutter 700, the cutter 700 is disposed at the rear side of the blister 100 along the conveying path of the first conveyor 200, and the first conveyor 200 is also disposed through the cutter 700, so that the cutter 700 can cut the material formed by the blister 100.

It should be understood that the cutting machine 700 includes an upper die unit 710 and a lower die unit 720, the upper die unit 710 includes a fifth driving member and an upper die table, the bottom of the upper die table is used for connecting a cutting board, the bottom of the cutting board is provided with a cutting knife, and the lower die unit 720 includes a sixth driving member and a lower die table. First conveyer 200 transported substance material is through going up between mould unit 710 and lower mould unit 720 after, and the mould platform drives the cutting board down in the drive of fifth driving piece, and the mould platform goes upward under the drive of sixth driving piece to realize the cutter to cutting of product, cutting this moment is not cut off completely, but can be comparatively easy with fashioned product from banding material separation.

It is understood that a lifting device 600 is further included, the lifting device 600 is disposed between the plastic sucking machine 100 and the clipper 700, the lifting device 600 is used for lifting a mold to a mold mounting area of the plastic sucking machine 100 and/or a cutter plate for the clipper 700 to a cutter plate mounting area of the clipper 700, and the mold includes an upper mold and a lower mold. For example, as shown in fig. 1 and 5, in this embodiment, a lifting device 600 may be further provided, the lifting device 600 may be provided between the plastic sucking machine 100 and the cutting machine 700, the lifting device 600 may be used to lift the upper mold and the lower mold to the mold mounting area of the plastic sucking machine 100, the lifting device 600 may be used to lift the knife board to the knife board mounting area of the cutting machine 700, or the lifting device 600 may lift the mold or lift the knife board, and the mold includes the upper mold and the lower mold. Therefore, the plastic suction production line can bear moulds of different models and cutting boards of different models, and before starting, workers move and install the moulds on the plastic suction machine 100 after lifting the moulds to the mould installation area, or move and install the cutting boards on the cutting machine 700 after lifting the cutting boards to the cutting board installation area.

It should be understood that in the present embodiment, a linear slide table 1100 is provided along the conveying path of the first conveyor 200, and the cutter 700 and the lifting device 600 are slidably connected to the linear slide table 1100, so that the lifting device 600 can be close to or away from the blister 100 and close to or away from the cutter 700 through the linear slide table 1100, and the cutter 700 can be close to the lifting device 600, so that the lifting device 600 can lift the mold and the knife board at the same time.

Specifically, elevating gear 600 is including the sliding stand 610, translation subassembly and the lifting unit that set gradually from bottom to top, and the translation subassembly passes through sliding stand 610 sliding connection on sharp slip table 1100, and the translation subassembly is including sharp module 620 and mount pad 630, and sharp module 620 sets up on sliding stand 610, and mount pad 630 horizontal sliding connection is in sharp module 620, and sharp module 620 is mutually perpendicular with sharp slip table 1100. The lifting assembly comprises a lifting platform 640 and a seventh driving member, the seventh driving member is disposed on the mounting base 630, and is used for driving the lifting platform 640 to lift. Thereby adjust the position of elevating platform 640 along first conveyer 200 delivery path through sharp slip table 1100, adjust the horizontal position of elevating platform 640 along perpendicular to first conveyer 200 delivery path through sharp module 620 to adjust the height of elevating platform 640 through the seventh driving piece, finally can lift the mould to the mould installation region of plastic uptake machine 100, also can lift the cutting board to the cutting board installation region of guillootine 700.

As shown in fig. 6, a plurality of fixing seats 641 may be further disposed on the lifting platform 640, each fixing seat 641 is provided with a rolling ball 642, and the cutting board and/or the mold are placed on the rolling ball 642. When the machine is started for use, the worker can move the knife plate and/or the die from the rolling ball 642 to the corresponding mounting area conveniently.

It is understood that a stacking mechanism 800 is provided along the conveying path of the first conveyor 200 at the rear side of the cutter 700, and the stacking mechanism 800 can eject and stack the materials at the escape position 220. For example, as shown in fig. 1 and 7, in the present embodiment, the blister line further includes a stacking mechanism 800, and the stacking mechanism 800 is provided at the rear side of the cutter 700 along the conveying path of the first conveyor 200, so that after the material is cut by the cutter 700, the cut product is ejected from the strip-shaped material and stacked by the stacking mechanism 800.

Specifically, in this embodiment, the stacking mechanism 800 includes a linear module 810, a connecting frame 820 and a plurality of suction nozzles 830, the first conveyor 200 and the stacking mechanism 800 are both disposed on the frame 1000, the linear module 810 is also disposed on the frame 1000, the linear module 810 is driven to be connected to the connecting frame 820, the plurality of suction nozzles 830 are disposed below the connecting frame 820, and the suction nozzles 830 are connected to a vacuum generating device, so that the suction nozzles 830 can suck the products and stack the products together in the process that the linear module 810 drives the connecting frame 820 to drive the suction nozzles 830 to descend. In other embodiments, the suction nozzle 830 can be replaced by a pneumatic gripper as long as the product can be picked and placed.

It is understood that a winder 900 is provided at the rear side of the stacking mechanism in the output direction of the first conveyor 200, and the winder 900 is used to wind the waste. For example, as shown in fig. 1, in the present embodiment, the blister line further includes a winding machine 900, and the winding machine 900 is disposed at the rear side of the stacking mechanism 800 along the conveying path of the first conveyor 200, so that after the stacking mechanism 800 ejects the product, the remaining material waste is conveyed by the first conveyor 200 and then collected by the winding machine 900. The collected waste materials can be crushed into waste material particles by the crusher and then poured into the extruder 300 again for melting, so that the recycling of the materials is realized.

It should be understood that in other embodiments, rather than providing the winder 900, a second conveyor and a shredder may be provided between the output of the first conveyor 200 and the extruder 300 for shredding the waste material produced after forming, cutting and stacking, and a second conveyor for conveying the waste material output by the first conveyor 200 to the shredder and the waste material particles produced by the shredder to the extruder 300.

The embodiments of the present application have been described in detail with reference to the drawings, but the present application is not limited to the embodiments, and various changes can be made within the knowledge of those skilled in the art without departing from the spirit of the present application. Furthermore, the embodiments and features of the embodiments of the present application may be combined with each other without conflict.

Claims (10)

1. Plastic uptake production line, its characterized in that includes:

the plastic suction machine comprises an upper die module and a lower die module which are arranged up and down correspondingly, the upper die module comprises a first driving assembly and an upper die base, the first driving assembly is used for driving the upper die base to lift, the bottom of the upper die base is used for being connected with an upper die, the lower die module comprises a second driving assembly and a lower die base, the second driving assembly is used for driving the lower die base to lift, the top of the lower die base is used for being connected with a lower die, the upper die or the lower die is provided with an air suction hole, and the upper die or the lower die is communicated with a negative pressure generating device through the air suction hole;

the first conveyor penetrates through the upper die module and the lower die module and is used for conveying materials, an avoiding position is formed in the middle of the first conveyor, and the avoiding position allows the upper die and the lower die to penetrate through and be matched with the die.

2. The blister line of claim 1, wherein the first conveyor comprises two sets of conveyor belt mechanisms, and the avoidance space is formed between the two sets of conveyor belt mechanisms.

3. The blister production line according to claim 1, wherein the lower mold has an air suction hole for communicating with the negative pressure generating device, and the upper mold has an air inlet hole for communicating with the air compressor.

4. The blister production line according to claim 1, wherein cooling water channels with water inlets and water outlets are provided in the upper mold and the lower mold.

5. The blister line of claim 1, wherein an extruder is disposed on a front side of the blister machine, the extruder being configured to melt and extrude the plastic log in a direction of the first conveyor.

6. The blister production line according to claim 5, wherein a roller press is arranged in the discharge direction of the extruder, the roller press is positioned at the front side of the blister machine, and the roller press is used for rolling the extruded plastic into a belt-shaped material with a required thickness.

7. The blister production line according to claim 1, wherein a cutter is provided along a conveying path of the first conveyor at a rear side of the blister machine, the cutter being capable of cutting the molded material through the avoiding position.

8. The blister production line according to claim 7, further comprising a lifting device, the lifting device being disposed between the blister machine and the cutter, the lifting device being configured to lift a mold to a mold mounting area of the blister machine and/or a blade of the cutter to a blade mounting area of the cutter, the mold comprising the upper mold and the lower mold.

9. The blister production line according to claim 7, wherein a stacking mechanism is provided along a conveying path of the first conveyor at a rear side of the cutter, the stacking mechanism being capable of ejecting and stacking the materials at the avoiding position.

10. The blister line of claim 9, wherein a winder is located at a rear side of the stacking mechanism in the output direction of the first conveyor, the winder being configured to wind waste.

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