CN114311385A - Anti-scald transparent injection molding cup thickening treatment process - Google Patents

Abstract

The invention belongs to the technical field of plastic cup processing, and particularly relates to a thickening treatment process of an anti-scald transparent injection molding cup, which comprises the following steps: step one, granulation: mixing the raw materials; step two, stirring: injecting the mixed PC plastic and carbon fiber into stirring equipment and stirring uniformly; step three, preparation: injecting the uniformly stirred PC plastic and carbon fiber into a double-screw extruder for extrusion; step four, cooling: cooling the raw materials, and introducing the cooled plastic raw materials into a granulator for granulation; step five, injection molding, namely melting the plastic particles obtained in the step four, injecting the melted plastic particles into an injection molding machine, and obtaining an injection molding cup through molding; and step six, surface treatment, namely trimming the corners of the molded injection molding cup by trimming. According to the invention, the outer ring and the stirring rod in the stirring equipment integrally rotate and move up and down at the same time, so that the integral stirring efficiency is effectively improved.

Description

Anti-scald transparent injection molding cup thickening treatment process

Technical Field

The invention relates to the technical field of plastic cup processing, in particular to a process for thickening an anti-scald transparent injection molding cup.

Background

The plastic cup comprises an injection molding cup and a plastic suction cup, the plastic cup and the injection molding cup have the following differences, the injection molding cup melts plastic raw material particles into fluid, the fluid is injected into a mold by an injection molding machine like a needle to be cooled to form the cup, the raw material used for the plastic suction forming is not the material particles, but the plastic particles are heated to a state that the plastic particles are softened and not melted, and the plastic particles are formed into a product by the mold.

When the injection molding cup is processed, a complete injection molding cup can be processed generally by continuous process steps of granulation, stirring, preparation, cooling, grain cutting, injection molding, surface treatment and the like.

Disclosure of Invention

Based on the technical problem that stirring efficiency of stirring equipment used in the injection cup processing technology is low, the invention provides a thickening treatment technology for an anti-scald transparent injection cup.

The invention provides a thickening treatment process of an anti-scald transparent injection molding cup, which comprises the following steps:

step one, granulation: raw materials are prepared according to the following steps of PC plastic: carbon fiber 1: 1, mixing;

step two, stirring: injecting the mixed PC plastic and carbon fiber into stirring equipment and stirring uniformly;

step three, preparation: injecting the uniformly stirred PC plastic and carbon fiber into a double-screw extruder combined with a granulator, and heating and extruding;

step four, cooling: cooling the plastic raw material extruded by the double-screw extruder, and introducing the cooled plastic raw material into a granulator for granulation;

step five, injection molding, namely melting the plastic particles obtained in the step four, injecting the melted plastic particles into an injection molding machine, and obtaining an injection molding cup through molding;

and step six, surface treatment, namely trimming the corners of the molded injection molding cup by trimming.

Preferably, the stirring device comprises a box body, a partition board is fixed in the box body through bolts, the inner wall of the bottom of the box body is rotatably connected with a main shaft through a bearing, the top of the main shaft penetrates through the partition board, the outer wall of one side of the main shaft is provided with a guide groove, a plurality of guide blocks which are uniformly distributed are connected in the guide groove in a sliding manner, the outer side of each guide block is fixedly provided with an inner ring through a bolt, the inner ring is sleeved on the main shaft, the outer wall of the circumference of the inner ring is provided with an outer ring groove, the inner ring is sleeved in the outer ring groove and is rotatably connected with an outer ring through a bearing, the outer wall of the circumference of the outer ring is fixedly provided with a plurality of stirring rods which are distributed in an annular array through bolts, a plurality of supporting rods which are distributed in an annular array are fixed between every two adjacent outer rings through bolts, the bottom of one outer ring positioned at the lowest position is fixedly provided with a plurality of collided blocks which are distributed in an annular array through bolts, a ring plate is sleeved on the top of the main shaft, the top of the loop bar is connected with an impact block, the cross sections of the impact block and the impacted block are both set to be arc-shaped, a limiting mechanism is arranged between the loop bar and the impact block, and the main shaft is connected with a driving mechanism.

Preferably, stop gear includes interior pole, and the embedded groove has been seted up at the loop bar top, and the spacing groove has been seted up to embedded groove rear end inner wall, and sliding connection has the stopper in the spacing groove, and interior pole passes through the bolt fastening in the front end of stopper, and interior pole passes through the bolt fastening in the bottom of striking piece, is provided with damper in the embedded groove.

Preferably, the damping mechanism comprises a first spring which is fixed between the inner wall of the bottom of the embedded groove and the inner rod through a bolt.

Preferably, damper includes the electro-magnet, and the electro-magnet passes through the bolt fastening in the bottom inner wall of embedded groove, and interior pole bottom bonds and has the permanent magnet, and the baffle bottom has the battery through the bolt fastening, battery and electro-magnet electric connection, and battery electric connection has energy storage mechanism, and energy storage mechanism includes annular magnet, and the inner ring groove has been seted up to outer loop circumference inner wall, and annular magnet bonds in the inner ring groove, and the inner ring bottom is seted up and is had the end annular groove, and end annular inslot bonds and is fixed with coil, coil and battery electric connection.

Preferably, the box top has the case lid through the bolt fastening, and the feed inlet has been seted up at the case lid top, and the feed inlet top has the feeder hopper through the bolt fastening, and the discharge gate has been seted up to box one side, and the discharge gate outside has the stock guide through the bolt fastening.

Preferably, the driving mechanism comprises a gear ring, the gear ring is sleeved and fixed on the main shaft, a motor is fixed on the inner wall of the bottom of the box body through a bolt, a first gear is connected to an output shaft of the motor, and the first gear is meshed and connected with the gear ring.

Preferably, the inner ring bottom both sides all are fixed with the fixed block through the bolt fastening, and the fixed block inboard has the reel through the bolt fastening, and a plurality of annular array distribution's movable groove is seted up to reel one side inner wall, and the sliding connection movable block in the movable groove has same second spring through the bolt fastening between movable block and the movable groove inner wall, and the movable block inboard has the cross-section to be curved about plate through the bolt fastening.

Preferably, the top of the spindle is fixed with a top plate through bolts, the top of the top plate is fixed with two guide rods which are symmetrically distributed through bolts, guide grooves are formed in the inner end faces of the guide rods, guide blocks are connected in the guide grooves in a sliding mode, connecting rods are fixed on the inner end faces of the guide blocks through bolts, toothed bars are fixed on the inner end faces of the connecting rods through bolts and penetrate through the top plate, rubber blocks are bonded to the bottom of the toothed bars, the same guide spring is fixed between one guide block and the corresponding inner wall of the top of the guide groove through bolts, lug blocks are fixed to the bottom of the top plate through bolts, the inner sides of the lug blocks are rotatably connected with shaft rods through bearings, second gears are fixed to the inner sides of the shaft rods through bolts, and the second gears and the two toothed bars are connected in a meshing mode.

Preferably, the spout has been seted up to feed inlet one side inner wall, and sliding connection has the slider in the spout, and feed inlet bottom one side articulates there is the shrouding, rotates through the bearing between shrouding and the slider and is connected with same branch, and the top of one of them ratch is passed through the bolt fastening and is had the ejector pin.

Compared with the prior art, the invention provides a thickening treatment process for an anti-scald transparent injection molding cup, which has the following beneficial effects:

1. this prevent scalding transparent injection molding cup thickening processing technology, starter motor, motor output shaft drives first gear revolve, then the meshing drives ring gear and main shaft rotation, drive the crown plate then, the whole and striking block of loop bar rotate, the striking block with receive the striking block to collide, when making the whole emergence pivoted of outer loop and puddler, the guide block is followed along the guide slot rebound together to outer loop and inner ring, after reaching the peak, because gravity falls back to initial position, thereby make the puddler carry out portable stirring, thereby effectively improve whole stirring efficiency.

2. This prevent scalding transparent cup thickening processing technology of moulding plastics, when the whole of outer loop fell back, the outer loop produced the extrusion to the piece of hitting for interior pole removed to the embedded groove along the spacing groove in, extrudeed first spring, thereby carries out the shock attenuation that slows down to the whole whereabouts process of outer loop.

3. This prevent scalding transparent injection molding cup thickening processing technology, the whole of outer loop and puddler rotates round the inner ring, synchronous drive ring magnet rotates, relative motion takes place before ring magnet and the coil, make the coil cut magnetic induction line motion, then produce induced-current, store in the battery, the battery supplies power for the electro-magnet, when the whole of outer loop falls back, the outer loop produces the extrusion to the piece of hitting, make interior pole remove to the embedded groove along the spacing groove in, electro-magnet and permanent magnet are close to gradually, magnetic repulsion between the two strengthens gradually, thereby reduce the shock attenuation to the whole whereabouts process of outer loop.

4. This prevent scalding transparent cup thickening processing technology of moulding plastics, twine the surface of a plurality of about plates with the wire of being connected between electro-magnet and the battery, again the wiring, when the electro-magnet rebound, produce pulling force to the wire, make a plurality of about plates tightened up, the second spring is compressed this moment, when the electro-magnet rebound, the pulling force to the wire production is relieved, this moment under the effect of second spring, make a plurality of about plates loosen, thereby reach the effect of bunch, prevent that the wire from relaxing, take place winding phenomenon.

5. This prevent scalding transparent cup thickening processing technology of moulding plastics, when the whole rebound of outer loop, form upwards thrust to one of them ratch, this ratch rebound, then the meshing drives second gear revolve, second gear meshing drives another ratch rebound, then with the outer loop contact, carry out the return push to the outer loop, thereby promote the holistic return journey of outer loop, thereby make the outer loop whole frequency that goes on reciprocating improve, thereby further improve whole stirring efficiency, and simultaneously, when ratch rebound, can drive the ejector pin removal simultaneously, the ejector pin is the jack-up that makes progress with the shrouding, seal the feed inlet, when the ejector pin moves down, the shrouding is because gravity resets and rotates, thereby make the feed inlet opened by intermittent type nature, thereby the orderly feeding of control raw and other materials, prevent that the feeding blocks up, thereby further improve whole stirring efficiency.

Drawings

FIG. 1 is a schematic view of the overall structure of a stirring apparatus according to the present invention;

FIG. 2 is a schematic structural diagram of a main shaft of the stirring device of the present invention;

FIG. 3 is an enlarged schematic view of a stirring device of the present invention at B;

FIG. 4 is an enlarged schematic view of the stirring device at A;

FIG. 5 is a schematic view of a split structure of an inner ring and an outer ring of the stirring device provided by the present invention;

FIG. 6 is a schematic view of the internal structure of the sleeve of the stirring device according to the present invention;

FIG. 7 is an enlarged schematic view of a stirring device according to the present invention at position C;

FIG. 8 is a schematic view of the top plate structure of the stirring device of the present invention;

FIG. 9 is a schematic structural view of a box cover of the stirring device according to the present invention;

fig. 10 is an enlarged schematic view of the stirring device according to the present invention at D.

In the figure: 1. a box body; 2. a partition plate; 3. a main shaft; 4. a guide groove; 5. a guide block; 6. an inner ring; 7. an outer ring groove; 8. an outer ring; 9. a stirring rod; 10. a collided block; 11. a support bar; 12. a ring plate; 13. a loop bar; 14. an impact block; 15. a toothed ring; 16. a motor; 17. a first gear; 18. a groove is embedded; 19. an inner rod; 20. a first spring; 21. a limiting groove; 22. a limiting block; 23. a permanent magnet; 24. an electromagnet; 25. a storage battery; 26. a bottom ring groove; 27. a coil; 28. an inner ring groove; 29. a ring magnet; 30. a fixed block; 31. a reel; 32. a movable groove; 33. a movable block; 34. a second spring; 35. a restraint plate; 36. a box cover; 37. a feed inlet; 38. a feed hopper; 39. a discharge port; 40. a material guide plate; 41. a top tray; 42. a guide bar; 43. a guide block; 44. a guide block; 45. a guide spring; 46. a connecting rod; 47. a rack bar; 48. a rubber block; 49. an ear piece; 50. a shaft lever; 51. a second gear; 52. a chute; 53. a slider; 54. a strut; 55. closing the plate; 56. and a push rod.

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.

Example 1

Referring to fig. 1-6, a thickening treatment process of an anti-scald transparent injection molding cup comprises the following steps:

step one, granulation: raw materials are prepared according to the following steps of PC plastic: carbon fiber 1: 1, mixing;

step two, stirring: injecting the mixed PC plastic and carbon fiber into stirring equipment and stirring uniformly;

step three, preparation: injecting the uniformly stirred PC plastic and carbon fiber into a double-screw extruder combined with a granulator, and heating and extruding;

step four, cooling: cooling the plastic raw material extruded by the double-screw extruder, and introducing the cooled plastic raw material into a granulator for granulation;

step five, injection molding, namely melting the plastic particles obtained in the step four, injecting the melted plastic particles into an injection molding machine, and obtaining an injection molding cup through molding;

and step six, surface treatment, namely trimming the corners of the molded injection molding cup by trimming.

Further, the stirring equipment comprises a box body 1, a partition plate 2 is fixed in the box body 1 through bolts, a main shaft 3 is rotatably connected to the inner wall of the bottom of the box body 1 through a bearing, the top of the main shaft 3 penetrates through the partition plate 2, a guide groove 4 is formed in the outer wall of one side of the main shaft 3, a plurality of guide blocks 5 which are uniformly distributed are slidably connected in the guide groove 4, an inner ring 6 is fixed on the outer side of each guide block 5 through bolts, the inner ring 6 is sleeved on the main shaft 3, an outer ring groove 7 is formed in the circumferential outer wall of the inner ring 6, an outer ring 8 is sleeved in the outer ring groove 7 and rotatably connected through the bearing, a plurality of stirring rods 9 which are distributed in an annular array are fixed on the circumferential outer wall of the outer ring 8 through bolts, a plurality of supporting rods 11 which are distributed in an annular array are fixed between two adjacent outer rings 8 through bolts, a plurality of collision blocks 10 which are distributed in an annular array are fixed at the bottom of the outer ring 8 which is located at the lowest part through bolts, and a ring plate 12 is sleeved on the main shaft 3, the top of the ring plate 12 is fixed with a plurality of loop bars 13 distributed in an annular array through bolts, the top of the loop bar 13 is connected with an impact block 14, the cross sections of the impact block 14 and the impacted block 10 are both set to be arc-shaped, a limiting mechanism is arranged between the loop bar 13 and the impact block 14, and the main shaft 3 is connected with a driving mechanism.

Further, stop gear includes interior pole 19, and embedded groove 18 has been seted up at loop bar 13 top, and spacing groove 21 has been seted up to embedded groove 18 rear end inner wall, and sliding connection has stopper 22 in the spacing groove 21, and interior pole 19 passes through the bolt fastening in stopper 22's front end, and interior pole 19 passes through the bolt fastening in the bottom of striking block 14, is provided with damper in the embedded groove 18.

Further, the damper mechanism includes a first spring 20, and the first spring 20 is fixed between the inner wall of the bottom of the insertion groove 18 and the inner rod 19 by a bolt.

Further, a box cover 36 is fixed to the top of the box body 1 through bolts, a feeding port 37 is formed in the top of the box cover 36, a feeding hopper 38 is fixed to the top of the feeding port 37 through bolts, a discharging port 39 is formed in one side of the box body 1, and a material guide plate 40 is fixed to the outer side of the discharging port 39 through bolts.

Further, actuating mechanism includes ring gear 15, and ring gear 15 cover is established and is fixed in on main shaft 3, and the inner wall of box 1 bottom has motor 16 through the bolt fastening, and motor 16 output shaft has first gear 17, and first gear 17 and ring gear 15 meshing are connected.

The working principle is as follows: when the material mixing device is used, raw materials are injected from the feed hopper 38, the motor 16 is started, an output shaft of the motor 16 drives the first gear 17 to rotate, then the first gear is meshed with the gear ring 15 and the main shaft 3 to rotate, then the ring plate 12, the whole of the loop bar 13 and the impact block 14 are driven to rotate, the impact block 14 collides with the impacted block 10, the outer ring 8 and the inner ring 6 move upwards along the guide groove 4 along with the guide block 5 while the whole of the outer ring 8 and the stirring rod 9 rotate, after the highest point is reached, the initial position is fallen back due to gravity, so that the stirring rod 9 is stirred movably, the whole stirring efficiency is effectively improved, the uniformly stirred raw materials are discharged through the discharge hole 39, further, when the whole of the outer ring 8 falls back, the outer ring 8 extrudes the impact inner rod 14, so that the first spring 20 is extruded after the outer ring 8 moves into the embedded groove 18 along with the limiting groove 21, thereby carrying out deceleration and shock absorption on the whole falling process of the outer ring 8.

Example 2

Referring to fig. 1 and 5-7, a prevent scalding transparent injection molding cup thickening processing technology, damper includes electro-magnet 24, electro-magnet 24 is fixed in the bottom inner wall of embedded groove 18 through the bolt, interior pole 19 bottom bonds and has permanent magnet 23, 2 bottoms of baffle have battery 25 through the bolt fastening, battery 25 and electro-magnet 24 electric connection, battery 25 electric connection has energy storage mechanism, energy storage mechanism includes annular magnet 29, 8 circumference inner walls of outer loop have seted up inner ring groove 28, annular magnet 29 bonds in inner ring groove 28, 6 bottoms of inner ring have seted up end annular groove 26, the bonding is fixed with coil 27 in end annular groove 26, coil 27 and battery 25 electric connection.

Further, 6 bottom both sides of inner ring all are fixed with fixed block 30 through the bolt fastening, and fixed block 30 is inboard to be fixed with reel 31 through the bolt fastening, and a plurality of annular array distribution's movable groove 32 has been seted up to reel 31 one side inner wall, sliding connection movable block 33 in the movable groove 32, has same second spring 34 through the bolt fastening between movable block 33 and the movable groove 32 inner wall, and movable block 33 is inboard to have the cross-section to be curved about plate 35 through the bolt fastening.

The working principle is as follows: when the electromagnetic shock absorber is used, the whole body of the outer ring 8 and the stirring rod 9 rotates around the inner ring 6 to synchronously drive the annular magnet 29 to rotate, relative motion occurs between the annular magnet 29 and the coil 27, so that the coil 27 cuts magnetic induction line motion to generate induced current, the induced current is stored in the storage battery 25, the storage battery 25 supplies power to the electromagnet 24, when the whole body of the outer ring 8 falls back, the outer ring 8 extrudes the impact block 14, the inner rod 19 moves to the embedded groove 18 along the limiting groove 21, the electromagnet 24 and the permanent magnet 23 gradually approach to each other, magnetic repulsion between the electromagnet 24 and the permanent magnet 23 is gradually enhanced, so that the reduction and shock absorption are performed on the whole falling process of the outer ring 8, further, the winding drum 31 is arranged, so that a lead connected between the electromagnet 24 and the storage battery 25 can be wound on the surfaces of the plurality of constraint plates 35 to be connected, then wiring is performed, when the electromagnet 24 moves upwards, the lead generates tension, make a plurality of about plates 35 tighten up, second spring 34 is compressed this moment, and when electro-magnet 24 moved down, the pulling force that produces the wire was relieved, at this moment under the effect of second spring 34 for a plurality of about plates 35 loosen, thereby reach the effect of bunch, prevent that the wire from relaxing, take place winding phenomenon.

Example 3

Referring to fig. 8-10, a thickening process for an anti-scald transparent injection molding cup, wherein a top plate 41 is fixed on the top of a main shaft 3 through a bolt, two guide rods 42 which are symmetrically distributed are fixed on the top of the top plate 41 through a bolt, a guide groove 43 is formed in the inner end surface of each guide rod 42, a guide block 44 is slidably connected in each guide groove 43, a connecting rod 46 is fixed on the inner end surface of each guide block 44 through a bolt, a toothed bar 47 is fixed on the inner end surface of each connecting rod 46 through a bolt, the toothed bar 47 penetrates through the top plate 41, a rubber block 48 is bonded on the bottom of each toothed bar 47, one of them guide block 44 and the corresponding guide way 43 top inner wall between be fixed with same direction spring 45 through the bolt, the dish 41 bottom has ear piece 49 through the bolt fastening, ear piece 49 inboard is connected with axostylus axostyle 50 through the bearing rotation, and axostylus axostyle 50 inboard has second gear 51 through the bolt fastening, and second gear 51 and two ratchets 47 all mesh and connect.

Further, a sliding groove 52 is formed in the inner wall of one side of the feed port 37, a sliding block 53 is connected in the sliding groove 52 in a sliding mode, a sealing plate 55 is hinged to one side of the bottom of the feed port 37, the sealing plate 55 and the sliding block 53 are rotatably connected through a bearing to form a same supporting rod 54, and a top rod 56 is fixed to the top of one toothed rod 47 through a bolt.

The working principle is as follows: during the use, when the whole rebound of outer loop 8, form upwards thrust to one of them ratch 47, this ratch 47 rebound, then the meshing drives second gear 51 and rotates, second gear 51 meshes and drives another ratch 47 rebound, then with the contact of outer loop 8, carry out the return push to outer loop 8, thereby promote the holistic return stroke of outer loop 8, thereby make the whole frequency that reciprocates that carries out of outer loop 8 improve, thereby further improve whole stirring efficiency, and simultaneously, when ratch 47 rebound, can drive ejector pin 56 simultaneously and remove, ejector pin 56 upwards jacks shrouding 55, seal feed inlet 37, when ejector pin 56 moves down, shrouding 55 rotates because gravity resets, thereby make feed inlet 37 opened by intermittent type nature, thereby the orderly feeding of control raw and other materials, prevent that the feeding blocks up, thereby further improve whole stirring efficiency.

In the description of the present invention, it is to be understood that the terms "central," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," "axial," "radial," "circumferential," and the like are used in the orientations and positional relationships indicated in the drawings for convenience in describing the invention and to simplify the description, and are not intended to indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and are therefore not to be considered limiting of the invention.

Claims (10)

1. The thickening treatment process of the anti-scald transparent injection molding cup is characterized by comprising the following steps of:

step one, granulation: raw materials are prepared according to the following steps of PC plastic: carbon fiber 1: 1, mixing;

step two, stirring: injecting the mixed PC plastic and carbon fiber into stirring equipment and stirring uniformly;

step three, preparation: injecting the uniformly stirred PC plastic and carbon fiber into a double-screw extruder combined with a granulator, and heating and extruding;

step four, cooling: cooling the plastic raw material extruded by the double-screw extruder, and introducing the cooled plastic raw material into a granulator for granulation;

step five, injection molding, namely melting the plastic particles obtained in the step four, injecting the melted plastic particles into an injection molding machine, and obtaining an injection molding cup through molding;

and step six, surface treatment, namely trimming the corners of the molded injection molding cup by trimming.

2. The thickening treatment process of the anti-scald transparent injection molding cup as claimed in claim 1, wherein the stirring device comprises a box body (1), a partition plate (2) is fixedly connected inside the box body (1), a main shaft (3) is rotatably connected to the inner wall of the bottom of the box body (1), the top of the main shaft (3) penetrates through the partition plate (2), a guide groove (4) is formed in the outer wall of one side of the main shaft (3), a plurality of guide blocks (5) which are uniformly distributed are slidably connected in the guide groove (4), an inner ring (6) is fixedly connected to the outer side of each guide block (5), the main shaft (3) is sleeved with the inner ring (6), an outer ring groove (7) is formed in the outer wall of the circumference of the inner ring (6), an outer ring (8) is sleeved and rotatably connected in the outer ring groove (7), a plurality of stirring rods (9) which are distributed in an annular array are fixedly connected to the outer wall of the outer ring (8), and a plurality of supporting rods (11) which are distributed in an annular array are fixedly connected between two adjacent outer rings (8), one of them is located outer ring (8) bottom fixedly connected with a plurality of annular array of the below and distributes and receives piece (10), the cover is established on main shaft (3) and is fixed with crown plate (12), crown bar (13) that a plurality of annular array of crown plate (12) top fixedly connected with distribute, crown bar (13) top is connected with striking piece (14), striking piece (14) and the piece (10) cross-section that receives are collided all set into the arc, be provided with stop gear between crown bar (13) and striking piece (14), main shaft (3) are connected with actuating mechanism.

3. The thickening treatment process for the anti-scald transparent injection molding cup according to claim 2, wherein the limiting mechanism comprises an inner rod (19), an embedded groove (18) is formed in the top of the loop bar (13), a limiting groove (21) is formed in the inner wall of the rear end of the embedded groove (18), a limiting block (22) is connected in the limiting groove (21) in a sliding mode, the inner rod (19) is fixedly connected to the front end of the limiting block (22), the inner rod (19) is fixedly connected to the bottom of the impact block (14), and a damping mechanism is arranged in the embedded groove (18).

4. The thickening process of the anti-scald transparent injection molding cup as claimed in claim 3, wherein the damping mechanism comprises a first spring (20), and the first spring (20) is fixedly connected between the inner wall of the bottom of the embedded groove (18) and the inner rod (19).

5. The thickening treatment process for the anti-scald transparent injection molding cup according to claim 3, wherein the damping mechanism comprises an electromagnet (24), the electromagnet (24) is fixedly connected to the inner bottom wall of the embedded groove (18), a permanent magnet (23) is bonded to the bottom of the inner rod (19), a storage battery (25) is fixedly connected to the bottom of the partition plate (2), the storage battery (25) is electrically connected with the electromagnet (24), the storage battery (25) is electrically connected with an energy storage mechanism, the energy storage mechanism comprises a ring magnet (29), an inner ring groove (28) is formed in the inner circumferential wall of the outer ring (8), the ring magnet (29) is bonded in the inner ring groove (28), a bottom ring groove (26) is formed in the bottom of the inner ring (6), a coil (27) is bonded and fixed in the bottom ring groove (26), and the coil (27) is electrically connected with the storage battery (25).

6. The thickening treatment process for the anti-scald transparent injection molding cup according to claim 2, wherein a box cover (36) is fixedly connected to the top of the box body (1), a feeding hole (37) is formed in the top of the box cover (36), a feeding hopper (38) is fixedly connected to the top of the feeding hole (37), a discharging hole (39) is formed in one side of the box body (1), and a material guide plate (40) is fixedly connected to the outer side of the discharging hole (39).

7. The thickening treatment process of the anti-scald transparent injection molding cup according to claim 2, wherein the driving mechanism comprises a toothed ring (15), the toothed ring (15) is sleeved and fixed on the main shaft (3), a motor (16) is fixedly connected to the inner wall of the bottom of the box body (1), an output shaft of the motor (16) is connected with a first gear (17), and the first gear (17) is meshed and connected with the toothed ring (15).

8. The thickening treatment process for the anti-scald transparent injection molding cup according to claim 6, wherein both sides of the bottom of the inner ring (6) are fixedly connected with fixed blocks (30), a winding drum (31) is fixedly connected to the inner side of each fixed block (30), a plurality of movable grooves (32) distributed in an annular array are formed in the inner wall of one side of each winding drum (31), movable blocks (33) are slidably connected in the movable grooves (32), a same second spring (34) is fixedly connected between the movable blocks (33) and the inner wall of each movable groove (32), and a restraint plate (35) with an arc-shaped cross section is fixedly connected to the inner side of each movable block (33).

9. The thickening treatment process for the anti-scald transparent injection molding cup according to claim 6, wherein a top plate (41) is fixedly connected to the top of the spindle (3), two guide rods (42) are symmetrically distributed and fixedly connected to the top of the top plate (41), guide grooves (43) are formed in inner end surfaces of the guide rods (42), guide blocks (44) are slidably connected to the guide grooves (43), connecting rods (46) are fixedly connected to the inner end surfaces of the guide blocks (44), toothed rods (47) are fixedly connected to the inner end surfaces of the connecting rods (46), the toothed rods (47) penetrate through the top plate (41), rubber blocks (48) are bonded to the bottoms of the toothed rods (47), one guide spring (45) is fixedly connected between one guide block (44) and the inner wall of the top of the corresponding guide groove (43), an ear block (49) is fixedly connected to the bottom of the top plate (41), and a shaft rod (50) is rotatably connected to the inner side of the ear block (49), the inner side of the shaft lever (50) is fixedly connected with a second gear (51), and the second gear (51) is meshed with the two toothed bars (47).

10. The thickening treatment process for the anti-scald transparent injection molding cup according to claim 9, wherein a sliding groove (52) is formed in the inner wall of one side of the feeding hole (37), a sliding block (53) is connected in the sliding groove (52) in a sliding manner, a sealing plate (55) is hinged to one side of the bottom of the feeding hole (37), a same supporting rod (54) is connected between the sealing plate (55) and the sliding block (53) in a rotating manner, and a top rod (56) is fixedly connected to the top of one toothed rod (47).

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