CN215550856U - Automatic change plastic uptake machine of design - Google Patents

Abstract

The application discloses automatic blister machine of design. The utility model provides an automatic plastic uptake machine of design can stabilize the blowing, can prevent that the sheet from dropping or taking place the skew in transmission process, can improve the compound die precision of cope match-plate pattern and lower bolster, improves the finished product quality, can improve the semi-manufactured goods stability of cutting, further improves the finished product quality.

Description

Automatic change plastic uptake machine of design

Technical Field

The application relates to the technical field of vacuum forming, in particular to a plastic uptake machine with automatic design.

Background

The plastic uptake machine generally needs to unreel the sheet through the material loading module, and the rethread transmission module transmits the sheet to heating module, forming module etc. in proper order, makes the sheet become soft through heating module, makes sheet plastic uptake shaping through forming module.

In the related art, the automatically designed plastic sucking machine is unstable in operation and low in finished product quality. For example, the feeding module is easy to jam, and the sheet conveyed by the conveying module is easy to shift.

Disclosure of Invention

The present application is directed to solving at least one of the problems in the prior art. To this end, the present application proposes an automated design of a vacuum molding machine.

An automated vacuum molding machine according to an embodiment of the present application includes:

the feeding module comprises a feeding frame, a discharging roller, a third driving assembly, a guide roller, a sliding frame, a movable roller and a travel switch; the feeding roller is used for unwinding the sheet; the third driving assembly is in driving connection with the discharging roller; the material guide roller is fixed on the material loading frame; the sliding frame is arranged on the feeding frame and arranged along the height direction of the feeding frame; the movable roller is connected with the sliding frame in a sliding mode, and after the sheet is unreeled by the unreeling roller, the sheet winds from the upper side of the guide roller to the lower side of the movable roller; the travel switch is arranged on a traveling path line of the movable roller, can be contacted with the movable roller and is electrically connected with the third driving assembly;

the heating module is used for heating the sheet and comprises a first fixed frame, a first movable frame, a second fixed frame, a second movable frame and a fourth driving assembly; the first fixing frame is fixed on the inner side of the case of the automatic design plastic uptake machine; the first movable frame is provided with a first furnace body, and the first movable frame can slide along the first fixed frame to enable the first furnace body to enter and exit the case; the second fixing frame is fixed on the inner side of the case; the second movable frame is provided with a second furnace body, the second movable frame can slide along the second fixed frame to enable the second furnace body to enter and exit the case, and a connecting frame is arranged between the second movable frame and the first movable frame; the fourth driving assembly is used for driving the first movable frame to slide along the first fixed frame, and the first movable frame drives the second movable frame to slide along the second fixed frame through the connecting frame;

the forming module is used for forming the sheet and comprises an upper die module and a lower die module, and the lower die module and the upper die module are arranged correspondingly;

the sheet is transmitted to the transmission module by the movable roller, and the transmission module is used for sequentially transmitting the sheet to the heating module and the forming module.

According to the automatic design plastic uptake machine of this application embodiment, have following beneficial effect at least: when the forming die does not perform forming work, the movable roller lifts up to a certain height along the sliding frame under the action of sheet tension. When forming die carries out the plastic uptake shaping to the sheet, the blowing roller continues to unreel the sheet, and the sheet can't continue to transmit, and simultaneously, the sheet of activity roller department will become lax, and the pulling force to the activity roller will reduce gradually, and the activity roller will descend gradually along the carriage, and until activity roller and travel switch touch, travel switch will turn off the second drive assembly, reach the effect that the automatic shutdown was loose the material. The movable roller presses on the sheet material, so that the sheet material can still keep a tensioning state. In addition, a projection is provided on each link for contacting and pushing the sheet; the first channel is arranged, and the chain link is arranged in the first channel in a sliding manner, so that the stability of the running posture of the conveying chain can be maintained; the second channel is arranged, and the protruding part is positioned in the second channel, so that the abrasion caused by direct contact between the protruding part and the conveying channel can be reduced; meanwhile, the second channel is communicated with the outside, when the transmission module of the embodiment of the application operates, the protruding portion is matched with the inner wall of the second channel to clamp the sheet, the function of fixing the sheet in the sheet conveying process is achieved, and the sheet is prevented from falling.

According to some embodiments of the present application, the automated vacuum molding machine further comprises a cutting module located behind the forming module, the formed sheet being transported by the forming module to the cutting module, the cutting module comprising:

the cutting frame is provided with an accommodating cavity on the inner side, and the accommodating cavity is used for accommodating a finished product;

the first bearing mechanism is arranged at the front end of the cutting frame and used for bearing the semi-finished product;

the second supporting mechanism is arranged on the upper side of the cutting frame and is positioned above the accommodating cavity, the second supporting mechanism comprises a turnover part and at least one supporting plate, the supporting plate is used for supporting a part to be cut in the semi-finished product, and the turnover part is used for enabling the supporting plate to turn over towards the accommodating cavity;

the clamping mechanism is arranged on the cutting frame and is positioned between the first supporting mechanism and the second supporting mechanism;

and the cutting mechanism is arranged on the cutting frame and is positioned at one side of the clamping mechanism close to the second bearing mechanism.

According to some embodiments of the present application, the upper mold module includes a first driving assembly and an upper mold base, the first driving assembly is in driving connection with the upper mold base, and an upper mold plate is fixed at the lower end of the upper mold base; the lower die module comprises a second driving assembly and a lower die base, the second driving assembly is connected with the lower die base in a driving mode, a lower die plate is fixed at the upper end of the lower die base, and the lower die plate and the upper die plate are arranged correspondingly.

According to some embodiments of the present application, a heat insulation device is disposed between the heating module and the molding module.

According to some embodiments of the application, heat-proof device includes fixed plate, heat insulating board, first drive assembly, the fixed plate is fixed in the frame, first drive assembly drive is connected the heat insulating board, the heat insulating board can with the fixed plate concatenation, and cut off the heating module with the shaping module.

According to some embodiments of the application, the shaping module still includes cooling device, cooling device is located go up the side of mould module, cooling device includes position adjustment subassembly, cold wind generator and fog spray generator, cold wind generator with fog spray generator locates respectively the position adjustment subassembly.

According to some embodiments of the application, the transport module comprises a transport chain and a seat, the sheet being transported by the movable roller between the chain and the seat.

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 present application is further described with reference to the following figures and examples, in which:

FIG. 1 is a cross-sectional view of an automated blister machine according to an embodiment of the present application;

fig. 2 is a perspective view of a loading module according to an embodiment of the present application;

fig. 3 is a perspective view of another perspective view of the loading module according to the embodiment of the present application;

FIG. 4 is a perspective view of a heating module of an embodiment of the present application;

fig. 5 is a perspective view of a molding module according to an embodiment of the present application;

FIG. 6 is a perspective view of a trimming module according to an embodiment of the present application;

FIG. 7 is an enlarged view taken at A in FIG. 1;

fig. 8 is a perspective view of a transmission module according to an embodiment of the present application.

Reference numerals:

the feeding device comprises a feeding module 100, a feeding rack 110, a discharging roller 120, a material guiding roller 130, a movable roller 140, a sliding frame 150, a travel switch 160, a third driving assembly 170 and a carrying assembly 180;

the heating device comprises a heating module 200, a first fixed frame 210, a first movable frame 220, a first furnace body 230, a connecting frame 240 and a second fixed frame 250; a second movable frame 260, a second furnace body 270 and a fourth driving assembly 280;

the molding module 300, the first driving assembly 310, the upper die holder 320, the upper die plate 330, the second driving assembly 340, the lower die holder 350 and the lower die plate 360;

a cutting module 400, an accommodating cavity 410, a cutting frame 420, a first supporting mechanism 430, a clamping mechanism 440, a cutting mechanism 450, a second supporting mechanism 460, a supporting plate 461 and a turnover part 462;

the transmission module 500, the base 510 and the conveying chain 520;

a frame 600; a sheet 700;

an insulation device 800, a fixing plate 810, an insulation board 820, a fifth driving assembly 830;

cooling device 900, position adjustment subassembly 910, cold wind generator 920, spout fog generator 930.

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 drawings are exemplary 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 automatic design plastic uptake machine according to the embodiment of the application comprises a feeding module 100, a heating module 200, a molding module 300 and a transmission module 500.

The feeding module 100 comprises a feeding frame 110, a discharging roller 120, a third driving assembly 170, a material guiding roller 130, a sliding frame 150, a movable roller 140 and a travel switch 160; the sheet 700 is wound on the discharging roller 120, and the discharging roller 120 is used for unwinding the sheet 700; the third driving component 170 is in driving connection with the discharging roller 120; the guide roller 130 is fixed on the feeding frame 110; the sliding frame 150 is arranged on the feeding frame 110, and the sliding frame 150 is arranged along the height direction of the feeding frame 110; the movable roller 140 is slidably connected with the sliding frame 150, and after being unreeled by the unreeling roller 120, the sheet 700 is wound from the upper side of the material guide roller 130 to the lower side of the movable roller 140; the travel switch 160 is arranged on the traveling path of the movable roller 140, the travel switch 160 can touch the movable roller 140, and the travel switch 160 is electrically connected with the third driving assembly 170;

as shown in fig. 1 to 3, the discharging roller 120 is provided independently, and the sheet 700 is wound on the discharging roller 120, and when loading, the discharging roller 120 needs to be placed on and fixed to the loading frame 110. In addition, the guide roller 130 is fixed on the feeding frame 110, the height position of the guide roller 130 is higher than that of the discharging roller 120, the horizontal position of the guide roller 130 is closer to the rear end of the feeding frame 110 than that of the discharging roller 120, and the guide roller 130 can play an auxiliary tensioning role on the sheet 700. Next, the horizontal position of the sliding frame 150 is closer to the rear end of the feeding frame 110 than the horizontal position of the material guide roller 130, the sliding frame 150 is disposed along the height direction, and both ends of the movable roller 140 are disposed on the sliding frame 150 and can ascend or descend along the sliding frame 150. The travel switch 160 is disposed at one side of the sliding frame 150 and close to the bottom end of the sliding frame 150, and a contact of the travel switch 160 is located on a traveling path of the movable roller 140, so that the movable roller 140 can contact with the contact of the travel switch 160 when descending to be close to the bottom end of the sliding frame 150.

When the feeding module 100 is used, the third driving assembly 170 drives the discharging roller 120 to rotate, the sheet 700 is unwound by the discharging roller 120, then the sheet 700 firstly bypasses from the upper side of the guide roller 130 and then bypasses from the lower side of the movable roller 140, after the sheet 700 is unwound from the lower side of the movable roller 140, the sheet 700 is transmitted to the transmission module 500, and the sheet 700 is sequentially transmitted to the heating module 200, the forming module 300 and the cutting module 400 at the rear end through the transmission module 500.

As will be appreciated, when the forming module 300 is not performing the blister operation, i.e., the sheet 700 is being transported, the sheet 700 is tensioned as a whole, and since the sheet 700 is located at the lower side of the movable roller 140, the sheet 700 gives an upward force to the movable roller 140, the movable roller 140 will move upward along the carriage 150, and will eventually be stabilized at a certain height.

When the forming die performs plastic suction forming on the sheet 700, the sheet 700 stops being conveyed, the discharging roller 120 continues to discharge the sheet 700, the sheet 700 gradually loosens, the force applied to the movable roller 140 gradually decreases, the movable roller 140 gradually descends due to the action of gravity, the movable roller 140 is pressed on the sheet 700 all the time, the sheet 700 can be kept tensioned until the movable roller 140 touches the travel switch 160, the travel switch 160 stops the third driving assembly 170, the discharging roller 120 stops feeding, and the effect of automatically stopping feeding is achieved.

In addition, the feeding module 100 further includes a carrying assembly 180, and the carrying assembly 180 is used for carrying the discharging roller 120 wound with the sheet 700 from the ground to the upper end of the upper rack 110.

As shown in fig. 1, the automatic vacuum molding machine of the present application further includes a frame 600, and the heating module 200, the molding module 300, and the transfer module 500 are disposed on the frame 600.

The heating module 200 is used for heating the sheet 700, and the heating module 200 comprises a first fixed frame 210, a first movable frame 220, a second fixed frame 250, a second movable frame 260 and a fourth driving assembly 280; the first fixing frame 210 is fixed on the inner side of the case of the automatic design plastic uptake machine; the first movable frame 220 is provided with a first furnace body 230, and the first movable frame 220 can slide along the first fixed frame 210 to enable the first furnace body 230 to enter and exit the chassis; the second fixing frame 250 is fixed at the inner side of the case; the second movable frame 260 is provided with a second furnace body 270, the second movable frame 260 can slide along the second fixed frame 250, so that the second furnace body 270 can enter and exit the case, and a connecting frame 240 is arranged between the second movable frame 260 and the first movable frame 220; the fourth driving assembly 280 is used for driving the first movable frame 220 to slide along the first fixed frame 210, and the first movable frame 220 drives the second movable frame 260 to slide along the second fixed frame 250 through the connecting frame 240.

As shown in fig. 1 and 4, a plate (not shown) can be mounted on the outer side of the frame 600 to form a housing, and the heating module 200 is mounted on the inner side of the housing.

As shown in fig. 4, the first fixing frame 210 is fixed to the rack 600, and the first fixing frame 210 is located inside the chassis. The first movable frame 220 can slide along the first fixed frame 210.

As shown in fig. 4, the second fixing frame 250 is fixed to the rack 600, and the second fixing frame 250 is located inside the chassis. The second movable frame 260 can slide along the second stationary frame 250.

When the heating module 200 heats the sheet 700, the sheet 700 passes through between the first furnace 230 and the second furnace 270, and the first furnace 230 and the second furnace 270 heat the sheet 700.

It can be understood that, when the first furnace body 230 and the second furnace body 270 need to be maintained, the fourth driving component 280 drives the first movable frame 220 to horizontally slide along the first fixed frame 210, and part of the first movable frame 220 moves to the outside of the chassis, so that the first furnace body 230 moves from the inside of the chassis to the outside of the chassis, and meanwhile, when the first movable frame 220 slides along the first fixed frame 210, the first movable frame 220 drives the second movable frame 260 to horizontally slide along the second fixed frame 250 in the same direction through the connecting frame 240, so that part of the second movable frame 260 moves to the outside of the chassis, so that the second furnace body 270 synchronously moves from the inside of the chassis to the outside of the chassis, which can facilitate maintenance personnel to maintain the first furnace body 230 and the second furnace body 270.

The molding module 300 is used to mold the sheet 700, and the molding module 300 includes an upper mold module and a lower mold module, which are disposed corresponding to the upper mold module.

As shown in fig. 1, the upper and lower mold blocks may be closed and the heated sheet 700 may be subjected to a blister molding.

Further, as shown in fig. 1, the sheet 700 is conveyed by the movable roller 140 to the conveying module 500, and the conveying module 500 is used to convey the sheet 700 to the heating module 200 and the molding module 300 in order.

It can be understood that the sheet 700 is unreeled from the feeding module 100 to the transferring module 500, the transferring module 500 transfers the sheet 700 to the heating module 200 for heating, and then the sheet 700 is transferred to the forming module 300 for blister forming.

According to some embodiments of the present application, the automated design blister machine further comprises a cutting module 400, the cutting module 400 being disposed behind the forming module 300, the formed sheet 700 being transported from the forming module 300 to the cutting module 400, the cutting module 400 comprising:

a cutting frame 420, wherein an accommodating cavity 410 is formed on the inner side of the cutting frame 420, and the accommodating cavity 410 is used for accommodating a finished product, wherein the finished product refers to the cut and formed sheet 700;

a first supporting mechanism 430, disposed at the front end of the cutting frame 420, for supporting a semi-finished product, wherein the semi-finished product refers to the formed sheet 700;

a second supporting mechanism 460 disposed on the upper side of the cutting frame 420 and located above the accommodating chamber 410, wherein the second supporting mechanism 460 includes a turning member 462 and at least one supporting plate 461, the supporting plate 461 is used for supporting a portion to be cut in the semi-finished product, and the turning member 462 is used for turning the supporting plate 461 toward the accommodating chamber 410;

a clamping mechanism 440 disposed on the cutting frame 420 and located between the first supporting mechanism 430 and the second supporting mechanism 460;

the cutting mechanism 450 is disposed on the cutting frame 420 and located on a side of the clamping mechanism 440 close to the second supporting mechanism 460.

It will be appreciated that the sheet 700 is vacuum formed into blanks by the forming modules 300, and the transfer module 500 pushes the blanks to transfer them from the forming module 300 at the front end to the cutting module 400, which cutting module 400 is capable of sequentially cutting the blanks into individual products and collecting them.

As shown in fig. 6, the front end of the cutting frame 420 is positioned close to the molding module 300, the semi-finished product is transferred from the front end of the cutting frame 420 to the upper side of the cutting frame 420, the first holding mechanism 430 is used to hold a portion of the semi-finished product close to the front end of the cutting frame 420, and the second holding mechanism 460 is used to hold a portion of the semi-finished product positioned on the upper side of the cutting frame 420, that is, a portion of the semi-finished product to be cut.

As shown in fig. 6, the clamping mechanism 440 is disposed between the first holding mechanism 430 and the second holding mechanism 460, and the cutting mechanism 450 is located on one side of the clamping mechanism 440, specifically, the cutting mechanism 450 is also located between the first holding mechanism 430 and the second holding mechanism 460. When the cutting module 400 cuts the semi-finished product, the clamping mechanism 440 can clamp the semi-finished product, and the cutting mechanism 450 cuts the semi-finished product along the width direction of the semi-finished product, so that the semi-finished product is partially formed into a single finished product.

It will be appreciated that the clamping mechanism 440 is capable of holding the blank as it is being cut, preventing the blank from shifting, and improving the quality of the finished product. In addition, first supporting mechanism 430 and second supporting mechanism 460 are located the both sides of clamping mechanism 440 respectively, can play a supporting role to the both sides that semi-manufactured goods were cut, can give a support to semi-manufactured goods when semi-manufactured goods are cut, improve the roughness of finished product incision department, further improve finished product quality.

As shown in fig. 6, the housing chamber 410 of the cutting frame 420 is located below a second holding mechanism 460, which includes two support plates 461 and a reversing member 462. After the finished product is formed, the clamping mechanism 440 releases the fixation of the semi-finished product, the turning part 462 turns the supporting plate 461, so that the supporting plate 461 is turned towards the accommodating cavity 410, and meanwhile, the finished product falls from the supporting plate 461 into the accommodating cavity 410, thereby completing the collection of the finished product and improving the production efficiency.

According to some embodiments of the present application, the upper mold module includes a first driving assembly 310, an upper mold base 320, the first driving assembly 310 drivingly connects the upper mold base 320, and an upper mold plate 330 is fixed to a lower end of the upper mold base 320; the lower die module comprises a second driving assembly 340 and a lower die base 350, the second driving assembly 340 is in driving connection with the lower die base 350, a lower die plate 360 is fixed at the upper end of the lower die base 350, and the lower die plate 360 and the upper die plate 330 are arranged correspondingly.

As shown in fig. 5, specifically, the first driving assembly 310 is fixed at a position of the frame 600 near the upper side, the lower end of the first driving assembly 310 is driven to connect the upper die holder 320, the lower end of the upper die holder 320 is used for fixing the upper die plate 330, the first driving assembly 310 can drive the upper die holder 320 to drive the upper die plate 330 to move downwards, similarly, the second driving assembly 340 is fixed at a position of the frame 600 near the lower side, the upper end of the second driving assembly 340 is driven to connect the lower die holder 350, the upper end of the lower die holder 350 is used for fixing the lower die plate 360, and the second driving assembly 340 can drive the lower die plate 360 to move upwards.

It will be appreciated that the upper and lower mold plates 330, 360 can be closed by the first and second drive assemblies 310, 340, and that when the upper and lower mold plates 330, 360 are closed, a cavity is formed between the upper and lower mold plates 330, 360, which cavity is used to shape the sheet 700.

In addition, it can be stated that the first driving assembly 310 includes a servo motor and an air cylinder, and the second driving assembly 340 also includes a servo motor and an air cylinder, that is, the upper die holder 320 and the lower die holder 350 are stably driven by the servo motor, and the accuracy of mold clamping between the upper mold plate 330 and the lower mold plate 360 is improved by the auxiliary driving of the air cylinder, so as to improve the product quality.

According to some embodiments of the present application, a heat insulation device 800 is disposed between the heating module 200 and the molding module 300.

As shown in fig. 1, the heat insulation apparatus 800 is used to reduce the circulation of air between the heating module 200 and the molding module 300, reduce the loss of hot air from the heating module 200, and reduce energy consumption.

According to some embodiments of the present application, the heat insulation apparatus 800 includes a fixing plate 810, a heat insulation plate 820, and a fifth driving assembly 830, wherein the fixing plate 810 is fixed to the frame 600, the fifth driving assembly 830 is connected to the heat insulation plate 820, and the heat insulation plate 820 can be spliced with the fixing plate 810 and insulate the heating module 200 and the molding module 300.

As shown in fig. 1 and 7, the fixing plate 810 is fixed to the frame 600, the fixing plate 810 is located above the heat insulation plate 820, and the fifth driving unit 830 can drive the heat insulation plate 820 to move up and down in the height direction, so that the heat insulation plate 820 is engaged with the fixing plate 810, thereby isolating the heating module 200 and the molding module 300.

It will be appreciated that when it is desired to transfer the sheet 700 from the heating module 200 to the molding module 300, a gap is left between the insulation board 820 and the fixing plate 810 so that the sheet 700 can be transferred from the heating module 200 to the molding module 300 through the gap. After the sheet 700 is transferred to the molding module 300, the fixing plate 810 is spliced with the insulation board 820 by the fifth driving assembly 830, so that the heating module 200 is spaced apart from the molding module 300, thereby reducing heat loss of the heating module 200.

According to some embodiments of the present application, the forming module 300 further includes a cooling device 900, the cooling device 900 is located beside the upper die module, the cooling device 900 includes a position adjusting assembly 910, a cold air generator 920 and an aerosol generator 930, and the cold air generator 920 and the aerosol generator 930 are respectively disposed on the position adjusting assembly 910.

As shown in fig. 5, the spray generator 930 can generate a spray, and the cold air generator 920 can diffuse the spray in and near the area between the upper mold module and the lower mold module, so that the temperature of each part in the area tends to be the same, and the sheet 700 can be cooled at each part at the same cooling rate, thereby reducing the occurrence of deformation of the sheet 700 due to uneven cooling rate.

It will be appreciated that the cool air generator 920 may rapidly reduce the temperature of the sheet 700 to facilitate subsequent processing of the sheet 700, and that the provision of the spray generator 930 may further increase the cooling rate of the sheet 700. Secondly, the position adjusting assembly 910 can adjust the positions of the cold air generator 920 and the fog generator 930, and the cold air generator 920 and the fog generator 930 can keep proper distances from the upper template 330 and the lower template 360 for the upper template 330 and the lower template 360 with different sizes, and better align the sheet 700.

According to some embodiments of the present application, the transfer module includes a conveying chain 520 and a housing 510, and the sheet 700 is transferred between the chain and the housing 510 by the movable roller 140.

As shown in fig. 8, after the sheet 700 is wound out from the lower side of the movable roller 140, the sheet 700 is transferred to the transfer module 500, and specifically, the sheet 700 is caught between the conveying chain 520 and the holder 510 and transferred to the heating module 200, the molding module 300, and the cutting module 400 at the rear end in sequence by the conveying chain 520.

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 gist 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 (7)

1. Automatic change plastic uptake machine of design, its characterized in that includes:

the feeding module comprises a feeding frame, a discharging roller, a third driving assembly, a guide roller, a sliding frame, a movable roller and a travel switch; the feeding roller is used for unwinding the sheet; the third driving assembly is in driving connection with the discharging roller; the material guide roller is fixed on the material loading frame; the sliding frame is arranged on the feeding frame and arranged along the height direction of the feeding frame; the movable roller is connected with the sliding frame in a sliding mode, and after the sheet is unreeled by the unreeling roller, the sheet winds from the upper side of the guide roller to the lower side of the movable roller; the travel switch is arranged on a traveling path line of the movable roller, can be contacted with the movable roller and is electrically connected with the third driving assembly;

the heating module is used for heating the sheet and comprises a first fixed frame, a first movable frame, a second fixed frame, a second movable frame and a fourth driving assembly; the first fixing frame is fixed on the inner side of the case of the automatic design plastic uptake machine; the first movable frame is provided with a first furnace body, and the first movable frame can slide along the first fixed frame to enable the first furnace body to enter and exit the case; the second fixing frame is fixed on the inner side of the case; the second movable frame is provided with a second furnace body, the second movable frame can slide along the second fixed frame to enable the second furnace body to enter and exit the case, and a connecting frame is arranged between the second movable frame and the first movable frame; the fourth driving assembly is used for driving the first movable frame to slide along the first fixed frame, and the first movable frame drives the second movable frame to slide along the second fixed frame through the connecting frame;

the forming module is used for forming the sheet and comprises an upper die module and a lower die module, and the lower die module and the upper die module are arranged correspondingly;

the sheet is transmitted to the transmission module by the movable roller, and the transmission module is used for sequentially transmitting the sheet to the heating module and the forming module.

2. The automated design blister machine of claim 1, further comprising a cutting module disposed rearward of the forming module, the formed sheet being transported by the forming module to the cutting module, the cutting module comprising:

the cutting frame is provided with an accommodating cavity on the inner side, and the accommodating cavity is used for accommodating a finished product;

the first bearing mechanism is arranged at the front end of the cutting frame and used for bearing the semi-finished product;

the second supporting mechanism is arranged on the upper side of the cutting frame and is positioned above the accommodating cavity, the second supporting mechanism comprises a turnover part and at least one supporting plate, the supporting plate is used for supporting a part to be cut in the semi-finished product, and the turnover part is used for enabling the supporting plate to turn over towards the accommodating cavity;

the clamping mechanism is arranged on the cutting frame and is positioned between the first supporting mechanism and the second supporting mechanism;

and the cutting mechanism is arranged on the cutting frame and is positioned at one side of the clamping mechanism close to the second bearing mechanism.

3. The automated design blister machine of claim 1, wherein the upper mold module comprises a first drive assembly, an upper mold base, the first drive assembly drivingly connected to the upper mold base, the lower end of the upper mold base securing an upper mold plate; the lower die module comprises a second driving assembly and a lower die base, the second driving assembly is connected with the lower die base in a driving mode, a lower die plate is fixed at the upper end of the lower die base, and the lower die plate and the upper die plate are arranged correspondingly.

4. The automated vacuum molding machine of claim 1 wherein a thermal insulation device is disposed between said heating module and said molding module.

5. The automatic vacuum molding machine of claim 4, wherein the heat insulation device comprises a fixing plate, a heat insulation plate and a first driving assembly, the fixing plate is fixed on the machine frame, the first driving assembly is connected with the heat insulation plate in a driving mode, and the heat insulation plate can be spliced with the fixing plate and can insulate the heating module and the molding module.

6. The automated vacuum molding machine of claim 1, wherein the molding module further comprises a cooling device, the cooling device is located beside the upper mold module, the cooling device comprises a position adjusting assembly, a cold air generator and an aerosol generator, and the cold air generator and the aerosol generator are respectively located on the position adjusting assembly.

7. The automated design blister machine of claim 1, wherein the transport module includes a conveyor chain and a seat, the sheet being transported by the movable roller between the chain and the seat.

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