CN216329672U - Conical double-screw extrusion injection molding equipment - Google Patents

Abstract

The utility model discloses conical double-screw extrusion injection molding equipment, relates to the field of injection molding equipment, and aims to solve the problem that the existing double-screw extrusion injection molding equipment cannot realize the continuous feeding of uniformly mixed injection molding raw materials. The device has a novel structure, can solve the problem that the double-screw extrusion injection molding equipment cannot realize the continuous feeding of uniformly mixed injection molding raw materials, and effectively prevents the injection molding raw materials after being uniformly melted and mixed from being locally cooled and molded.

Description

Conical double-screw extrusion injection molding equipment

Technical Field

The utility model relates to the field of injection molding equipment, in particular to conical double-screw extrusion injection molding equipment.

Background

The conical double-screw extruder is a high-efficiency mixing and extruding device. The machine has the characteristics of small shearing rate, difficult material decomposition, uniform plasticizing and mixing, stable quality, high yield, wide application range, long service life and the like.

The problem that traditional toper double screw extrusion injection moulding equipment can't realize the raw materials continuity of moulding plastics feeding of homogeneous mixing, need transport the raw materials after the homogeneous mixing inside extrusion equipment's feed inlet to lead to it to cause the raw materials cooling forming of moulding plastics after the hot melt easily in the transportation, influence follow-up extrusion step of moulding plastics, consequently, in order to solve this type of problem, we have proposed a toper double screw extrusion injection moulding equipment.

SUMMERY OF THE UTILITY MODEL

The utility model provides conical double-screw extrusion injection molding equipment, which solves the problem that the existing double-screw extrusion injection molding equipment cannot realize the continuous feeding of uniformly mixed injection molding raw materials.

In order to achieve the purpose, the utility model adopts the following technical scheme:

a conical double-screw extrusion injection molding device comprises a machine body and a hot-melt mixing hopper, wherein the hot-melt mixing hopper is fixedly arranged at the top end of the machine body, a support is fixedly arranged at the upper section of the inner wall of the hot-melt mixing hopper, a first driven conical gear is rotatably arranged at the top end of the support, a rotating rod is fixedly connected to the bottom end of the first driven conical gear, the rotating rod penetrates through the support, and a plurality of stirring rods with the same structure are fixedly arranged in the hot-melt mixing hopper;

the hot melt mixer is characterized in that a material collecting groove and a mounting groove are formed in the machine body, the material collecting groove and the mounting groove are communicated with each other, the mounting groove is internally and rotatably provided with two conical feed rods with the same structure, a fixing plate is arranged at the communication position of the material collecting groove and the hot melt mixing hopper, the bottom end of the fixing plate is rotatably provided with a discharging plate and a second driven conical gear which coaxially and synchronously rotate, two symmetrically distributed material guide openings are formed in a plate body of the fixing plate, two symmetrically distributed discharging openings are formed in the discharging plate and the second driven conical gear, and the discharging openings and the material guide openings are identical in structure;

a double-shaft motor is fixedly mounted on one side of the machine body, a first transmission mechanism is connected between an output shaft at one end of the double-shaft motor and the first driven bevel gear, and a second transmission mechanism is connected between an output shaft at the other end of the double-shaft motor and the second driven bevel gear.

By adopting the technical scheme, the double-shaft motor drives the first driven bevel gear to rotate through the first driving mechanism, so that the first driven bevel gear drives the rotating rod and the stirring rod to rotate, the injection molding raw material guided into the hot-melting mixing hopper is subjected to hot-melting mixing stirring through the stirring rod, the hot-melting is uniform, the double-shaft motor drives the second driving mechanism to drive the second driven bevel gear to rotate, the second driven bevel gear synchronously drives the blanking plate to rotate, so that the blanking port on the blanking plate and the material guide port on the fixed plate are overlapped in an intermittent manner, the hot-melted injection molding raw material is orderly guided into the material collecting tank when being overlapped, and enters the mounting groove from the material collecting tank, and the injection molding raw material is extruded through the two rotating conical feeding rods, thereby the step of transferring the hot-melted injection molding raw material can be omitted, and the injection molding raw material after being uniformly hot-melted is effectively prevented from being subjected to local cooling molding, meanwhile, the injection molding raw materials can be fed in order after being uniformly mixed by hot melting, and the accumulation of the injection molding raw materials is avoided.

Preferably, the bracket is arranged in a cross-shaped structure, and the first driven bevel gear is located at the cross center of the bracket.

Through adopting above-mentioned technical scheme, through the setting of "ten" style of calligraphy structure of support, can make its inner wall at hot melt mixing hopper more stable to be located the cross central point of this support with first driven bevel gear and put, more stable when can guaranteeing that first driven bevel gear drives dwang and puddler and rotate, and help going into the inside raw materials of moulding plastics of hot melt mixing hopper and carry out even stirring.

Preferably, the first driving mechanism comprises a main belt pulley, an auxiliary belt pulley, a transmission rod and a first driving bevel gear, the main belt pulley is fixedly installed at an output shaft at one end, far away from the machine body, of the double-shaft motor, the transmission rod is installed at the top end of the support in a rotating mode, the auxiliary belt pulley and the first driving bevel gear are respectively and fixedly installed at two ends of the transmission rod, the first driving bevel gear is close to the first driven bevel gear and meshed with the first driven bevel gear, and a transmission belt is connected between the auxiliary belt pulley and the main belt pulley.

Through adopting above-mentioned technical scheme, the biax motor drives main belt pulley and rotates, and main belt pulley passes through driving belt and drives vice belt pulley and rotate, and vice belt pulley can drive transfer line and first drive conical gear and rotate, drives first driven conical gear rotation then, provides power for first driven conical gear.

Preferably, the first driving mechanism further comprises two supporting plates which are symmetrically distributed, the two supporting plates are fixedly mounted at the top end of the support, and the transmission rod penetrates through the supporting plates and is rotatably connected with the supporting plates.

Through adopting above-mentioned technical scheme, the backup pad can guarantee that the transfer line rotates steadily, protects the transfer line, prevents that the transfer line installation is unstable to lead to the production accident to take place.

Preferably, the second driving mechanism includes a second driven fluted disc, a second driving bevel gear and a driving fluted disc, the driving fluted disc is fixedly mounted at an end portion of the output shaft of the double-shaft motor extending to the inside of the material collecting tank, the second driven fluted disc and the second driving bevel gear are coaxially and synchronously rotatably mounted above the driving fluted disc, the driving fluted disc is meshed with the second driven fluted disc, and the second driving bevel gear is meshed with the second driven bevel gear.

Through adopting above-mentioned technical scheme, the biax motor drives the drive fluted disc and rotates, the drive fluted disc drives the driven fluted disc of second and rotates, the driven fluted disc of second drives the rotation of second drive conical gear, the driven conical gear of second drives the rotation of second driven conical gear, make the synchronous flitch rotation down that drives of the driven conical gear of second, make the feed opening intermittent type formula on the flitch and the guide mouth coincidence on the fixed plate down, can make the even mixture of stirring mould plastics the raw materials and enter into the material collecting tank in order inside from this, avoid lasting the raw materials that the unloading leads to and pile up the phenomenon and take place.

Preferably, the inner wall of one side of the material collecting groove close to the driving fluted disc is rotatably provided with two first driven fluted discs which are symmetrically distributed, the two first driven fluted discs are respectively positioned at two sides of the driving fluted disc and are meshed with the driving fluted disc, and the two first driven fluted discs respectively correspond to the two conical feeding rods one by one and are fixedly connected with driven rods.

Through adopting above-mentioned technical scheme, the drive fluted disc can drive first driven fluted disc in step and rotate, and first driven fluted disc drives the driven lever and rotates, and the driven lever drives toper feed rod again and rotates, provides power for the toper feed rod to need not to set up unnecessary driving motor again and remove to drive the rotation of toper feed rod, be favorable to resources are saved.

Preferably, a runner communicated with each other is arranged between the mounting groove and the material collecting groove, and the whole runner is obliquely arranged.

Through adopting above-mentioned technical scheme, the runner slope is provided with and helps the inside misce bene raw materials of moulding plastics of collecting groove to enter into the mounting groove inside, effectively avoids the extravagant phenomenon of material to take place.

The utility model has the beneficial effects that:

drive main belt pulley through the biax motor and rotate, thereby can drive vice belt pulley through driving belt and rotate, the dwang and puddler rotation can be ordered about in the rotation that rethread transfer line drove first drive conical gear and first driven conical gear, carry out even mixing stirring through the puddler to the inside raw materials of moulding plastics of hot melt mixing hopper and handle, need not earlier to mix the raw materials of moulding plastics, then transport to the hopper inside again, perhaps can be with the leading-in hot melt mixing hopper inside heating stirring once more of the raw materials of moulding plastics after the hot melt mixes and mix, the effectual mixed raw materials after the hot melt that prevents takes place the condition emergence of local cooling shaping when transporting to the hopper.

Drive the rotation of drive fluted disc through driving motor, thereby can drive first driven fluted disc and the rotation of the driven fluted disc of second, then can drive the rotation of second drive conical gear through the driven fluted disc of second, second drive conical gear drives the rotation of the driven conical gear of second, thereby can make the lower flitch rotate thereupon, make the feed opening on the lower flitch and the guide mouth intermittent type coincidence on the fixed plate, thereby can make the orderly feeding into of the raw materials that moulds plastics after the hot melt mixes the material and gather inside the silo, and drive driven lever and toper feed rod through first driven fluted disc and rotate, the raw materials that will mould plastics realizes the continuity and extrudes the operation.

In conclusion, the device can solve the problem that the injection molding raw material continuous feeding of the double-screw extrusion injection molding equipment which can not realize uniform mixing can effectively prevent the injection molding raw material after hot melt mixing from occurring in the condition of local cooling forming.

Drawings

FIG. 1 is a schematic structural view of a conical twin-screw extrusion injection molding apparatus of the present invention;

FIG. 2 is a first schematic cross-sectional view of a conical twin-screw extrusion injection molding apparatus of the present invention;

FIG. 3 is a second schematic cross-sectional view of a conical twin-screw extrusion injection molding apparatus of the present invention;

FIG. 4 is an enlarged schematic view of A in FIG. 3 of a conical twin-screw extrusion injection molding apparatus according to the present invention.

Reference numbers in the figures: 1. a body; 2. a double-shaft motor; 3. a primary pulley; 4. a secondary pulley; 5. a hot melt mixing hopper; 6. a support; 7. a transmission rod; 8. a support plate; 9. a first drive bevel gear; 10. a first driven bevel gear; 11. rotating the rod; 12. a material collecting groove; 13. a stirring rod; 14. a first driven fluted disc; 15. a driven lever; 16. a tapered feed bar; 17. mounting grooves; 18. a fixing plate; 19. a blanking plate; 20. a second driven fluted disc; 21. a second drive bevel gear; 22. a second driven bevel gear; 23. a feeding port; 24. the fluted disc is driven.

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.

Referring to fig. 1, the conical double-screw extrusion injection molding equipment comprises an equipment body 1 and a hot-melt mixing hopper 5, wherein the hot-melt mixing hopper 5 is fixedly arranged at the top end of the equipment body 1, a support 6 is fixedly arranged at the upper section of the inner wall of the hot-melt mixing hopper 5, a first driven conical gear 10 is rotatably arranged at the top end of the support 6, the support 6 is arranged in a cross-shaped structure, and the inner wall of the hot-melt mixing hopper 5 can be more stable through the cross-shaped structure of the support;

bottom fixedly connected with dwang 11 of first driven conical gear 10, and dwang 11 runs through support 6, and extend to the inside of hot melt mixing hopper 5 and fixed mounting has a plurality of puddlers 13 that the structure is the same, dwang 11 rotates with support 6 to be connected, first driven conical gear 10 is located the cross central point of this support 6 and puts, the cross central point that is located this support with first driven conical gear 10 puts, it is more stable when can guarantee that first driven conical gear 10 drives dwang 11 and puddler 13 and rotates, and help going into the inside raw materials of moulding plastics of hot melt mixing hopper 5 and carry out the even stirring.

Referring to fig. 1 and 2, a double-shaft motor 2 is fixedly mounted on one side of a machine body 1, a first driving mechanism is connected between an output shaft at one end of the double-shaft motor 2 and a first driven bevel gear 10, the first driving mechanism comprises a main belt pulley 3, an auxiliary belt pulley 4, a transmission rod 7, support plates 8 and a first driving bevel gear 9, the main belt pulley 3 is fixedly mounted on an output shaft at one end of the double-shaft motor 2, which is far away from the machine body 1, a transmission rod 7 is rotatably mounted at the top end of a support 6, two support plates 8 are fixedly mounted at the top end of the support 6, the transmission rod 7 penetrates through the support plates 8 and is rotatably connected with the support plates 8, the support plates 8 can ensure that the transmission rod 7 stably rotates to protect the transmission rod 7, and production accidents caused by instable mounting of the transmission rod 7 are prevented;

vice belt pulley 4 and first drive conical gear 9 are fixed mounting respectively in the both ends of transfer line 7, and first drive conical gear 9 is close to first driven conical gear 10, and intermeshing, be connected with driving belt between vice belt pulley 4 and the main belt pulley 3, double-shaft motor 2 drives main belt pulley 3 and rotates, main belt pulley 3 drives vice belt pulley 4 through driving belt and rotates, vice belt pulley 4 can drive transfer line 7 and first drive conical gear 9 and rotate, then drive first driven conical gear 10 and rotate, provide power for first driven conical gear 10.

The double-shaft motor 2 drives the first driven bevel gear 10 to rotate through the first driving mechanism, so that the first driven bevel gear 10 drives the rotating rod 11 and the stirring rod 13 to rotate, and the injection molding raw materials introduced into the hot-melt mixing hopper 5 are subjected to hot-melt mixing stirring through the stirring rod 13, so that the hot melt is uniform.

Referring to fig. 2, a material collecting groove 12 and a mounting groove 17 are formed in a machine body 1, the material collecting groove 12 and the mounting groove 17 are communicated with each other, the material collecting groove 12 and a hot melt mixing hopper 5 are communicated with each other, a flow channel communicated with each other is formed between the mounting groove 17 and the material collecting groove 12, the whole flow channel is obliquely arranged, the oblique arrangement of the flow channel is beneficial to the injection molding raw materials uniformly mixed in the material collecting groove 12 to enter the mounting groove 17, and the phenomenon of material waste is effectively avoided as much as possible;

two toper feed rods 16 that the structure is the same are installed to the rotation in mounting groove 17, fixed plate 18 is installed with the intercommunication department of hot melt blending hopper 5 to the groove 12 that gathers materials, and the bottom of fixed plate 18 rotates and installs coaxial synchronous pivoted lower plate 19 and the driven bevel gear 22 of second, set up two guide mouths that are symmetric distribution on the plate body of fixed plate 18, all set up two feed openings 23 that are symmetric distribution on lower plate 19 and the driven bevel gear 22 of second, and feed opening 23 is the same with guide mouth structure.

Referring to fig. 3 and 4, a second driving mechanism is connected between an output shaft at the other end of the dual-shaft motor 2 and the second driven bevel gear 22, the second driving mechanism includes a second driven fluted disc 20, a second driving bevel gear 21 and a driving fluted disc 24, the driving fluted disc 24 is fixedly mounted at an end portion of the output shaft of the dual-shaft motor 2 extending to the inside of the material collecting tank 12, the driving fluted disc 24 is rotatably mounted on an inner side wall of the machine body 1, the second driven fluted disc 20 and the second driving bevel gear 21 are coaxially and synchronously rotatably mounted on the inner side wall of the machine body 1 at a position above the driving fluted disc 24, the driving fluted disc 24 is engaged with the second driven fluted disc 20, and the second driving bevel gear 21 is engaged with the second driven bevel gear 22;

biax motor 2 drives drive fluted disc 24 and rotates, drive fluted disc 24 drives the driven fluted disc 20 rotation of second, the driven fluted disc 20 of second drives bevel gear 21 and rotates, second drive bevel gear 21 drives the driven bevel gear 22 rotation of second, make the driven bevel gear 22 synchronous drive down flitch 19 rotate, make the coincidence of the guide mouth on 23 intermittent type formulas of feed opening on the flitch 19 and the fixed plate 18 down, can make the even mixture of stirring mould plastics the raw materials and enter into in order inside the silo 12 that gathers materials, avoid the raw materials that the unloading leads to of lasting as far as possible and pile up the phenomenon and take place.

Referring to fig. 4, the inner wall of one side of the material collecting groove 12 close to the driving fluted disc 24 is rotatably provided with two first driven fluted discs 14 which are symmetrically distributed, and the two first driven fluted discs 14 are respectively located at two sides of the driving fluted disc 24, and the first driven fluted disc 14 is meshed with the driving fluted disc 24, the two first driven fluted discs 14 are respectively corresponding to the driven rods 15 between the two taper feeding rods 16, the driving fluted disc 24 can synchronously drive the first driven fluted disc 14 to rotate, the first driven fluted disc 14 drives the driven rods 15 to rotate, the two driven rods 15 are connected with the corresponding taper feeding rods 16 through universal joints, the driven rods 15 drive the taper feeding rods 16 to rotate, power is provided for the taper feeding rods 16, thereby unnecessary driving motors are not required to be arranged to drive the taper feeding rods 16 to rotate, and resource saving is facilitated.

Drive the driven bevel gear 22 rotation of second that second actuating mechanism drives through biax motor 2, flitch 19 rotates under the driven bevel gear 22 synchronous drive of second for the coincidence of the feed opening on flitch 19 and the guide mouth intermittent type formula on the fixed plate 18 down, with the raw materials of moulding plastics after the hot melt leading-in order to the silo 12 inside that gathers materials when the coincidence, and inside entering into mounting groove 17 by the silo 12 that gathers materials, will mould plastics the raw materials and extrude through two pivoted toper stack feeders 16 can.

The specific implementation mode of the conical double-screw extrusion injection molding equipment is as follows:

the injection molding raw materials are led into the hot melt mixing hopper 5, the double-shaft motor 2 drives the first driven bevel gear 10 to rotate through the first driving mechanism, so that the first driven bevel gear 10 drives the rotating rod 11 to rotate, the rotating rod 11 drives the stirring rod 13 to rotate, and the stirring rod 13 is used for mixing and stirring the injection molding raw materials in the hot melt mixing hopper 5;

meanwhile, the double-shaft motor 2 drives the second driven bevel gear 22 to rotate through the second driving mechanism, so that the second driven bevel gear drives the blanking plate 19 to rotate, a blanking port on the blanking plate 19 and a material guide port on the fixed plate 18 are overlapped intermittently, the hot-melted injection molding raw materials are sequentially guided into the material collecting groove 12 during overlapping, enter the installation groove 17 from the material collecting groove 12, and are extruded through the two rotating conical feeding rods 16;

the step of transporting the raw materials of moulding plastics after can saving from this and mix the hot melt, effectively prevent that the raw materials of moulding plastics after the hot melt misce bene from taking place the circumstances of local cooling shaping and taking place, can realize the raw materials of moulding plastics ordered feeding after the hot melt misce bene simultaneously, avoid the raw materials of moulding plastics to pile up the circumstances as far as possible and take place.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and equivalent alternatives or modifications according to the technical solution of the present invention and the inventive concept thereof should be covered by the scope of the present invention.

Claims (7)

1. The conical double-screw extrusion injection molding equipment comprises an engine body (1) and a hot-melt mixing hopper (5), and is characterized in that the hot-melt mixing hopper (5) is fixedly installed at the top end of the engine body (1), a support (6) is fixedly installed at the upper section of the inner wall of the hot-melt mixing hopper (5), a first driven bevel gear (10) is rotatably installed at the top end of the support (6), a rotating rod (11) is fixedly connected to the bottom end of the first driven bevel gear (10), the rotating rod (11) penetrates through the support (6), and a plurality of stirring rods (13) with the same structure are fixedly installed inside the hot-melt mixing hopper (5);

a material collecting groove (12) and a mounting groove (17) are arranged in the machine body (1), the material collecting groove (12) and the mounting groove (17) as well as the material collecting groove (12) and the hot melt mixing hopper (5) are communicated with each other, two conical feeding rods (16) with the same structure are rotatably arranged in the mounting groove (17), a fixed plate (18) is arranged at the communication part of the material collecting groove (12) and the hot melt mixing hopper (5), and the bottom end of the fixed plate (18) is rotatably provided with a blanking plate (19) and a second driven bevel gear (22) which coaxially and synchronously rotate, two symmetrically-distributed material guide openings are formed in the plate body of the fixing plate (18), two symmetrically-distributed feed openings (23) are formed in the blanking plate (19) and the second driven bevel gear (22), and the feed openings (23) are identical in structure to the material guide openings;

a double-shaft motor (2) is fixedly mounted on one side of the machine body (1), a first driving mechanism is connected between an output shaft at one end of the double-shaft motor (2) and the first driven bevel gear (10), and a second driving mechanism is connected between an output shaft at the other end of the double-shaft motor (2) and the second driven bevel gear (22).

2. A tapered twin-screw extrusion injection molding apparatus according to claim 1, wherein the holder (6) is provided in a cross-shaped configuration, and the first driven bevel gear (10) is located at a criss-cross center position of the holder (6).

3. The conical twin-screw extrusion injection molding device according to claim 1, wherein the first driving mechanism comprises a primary pulley (3), a secondary pulley (4), a transmission rod (7) and a first driving conical gear (9), the primary pulley (3) is fixedly installed at one end output shaft of the double-shaft motor (2) far away from the machine body (1), the transmission rod (7) is rotatably installed at the top end of the support (6), the secondary pulley (4) and the first driving conical gear (9) are respectively and fixedly installed at two ends of the transmission rod (7), the first driving conical gear (9) is close to the first driven conical gear (10) and is meshed with each other, and a transmission belt is connected between the secondary pulley (4) and the primary pulley (3).

4. A conical twin-screw extrusion injection molding apparatus according to claim 3, wherein the first driving mechanism further comprises two support plates (8) symmetrically distributed, and the two support plates (8) are fixedly installed at the top end of the bracket (6), and the transmission rod (7) penetrates the support plates (8) and is rotatably connected with the support plates (8).

5. The conical twin-screw extrusion injection molding device according to claim 1, wherein the second driving mechanism comprises a second driven fluted disc (20), a second driving conical gear (21) and a driving fluted disc (24), the driving fluted disc (24) is fixedly mounted at the end of the output shaft of the double-shaft motor (2) extending to the inside of the collecting groove (12), the second driven fluted disc (20) and the second driving conical gear (21) are coaxially and synchronously rotatably mounted above the driving fluted disc (24), the driving fluted disc (24) is meshed with the second driven fluted disc (20), and the second driving conical gear (21) is meshed with the second driven conical gear (22).

6. The tapered twin-screw extrusion injection molding device according to claim 5, wherein the inner wall of the material collecting groove (12) close to one side of the driving fluted disc (24) is rotatably provided with two first driven fluted discs (14) which are symmetrically distributed, the two first driven fluted discs (14) are respectively positioned at two sides of the driving fluted disc (24), the first driven fluted disc (14) is meshed with the driving fluted disc (24), and driven rods (15) are fixedly connected between the two first driven fluted discs (14) and the two tapered feeding rods (16) in a one-to-one correspondence manner.

7. The conical twin-screw extrusion injection molding apparatus according to claim 1, wherein a runner is provided between the mounting groove (17) and the collecting groove (12), and the runner is inclined as a whole.

Images