CN110696365B - 3D prints plastics substrate recovery processing equipment - Google Patents

Abstract

The invention relates to plastic processing equipment, in particular to 3D printing plastic substrate recovery processing equipment which comprises a rotary material storage mechanism, a feeding shell mechanism and a stirring mechanism, wherein the equipment can store plastic substrates, can feed materials, can prevent material blockage, can ensure power transmission, and can stir plastics, the rotary material storage mechanism is connected with the feeding shell mechanism, and the feeding shell mechanism is connected with the stirring mechanism.

Description

3D prints plastics substrate recovery processing equipment

Technical Field

The invention relates to a plastic processing device, in particular to a 3D printing plastic substrate recovery processing device.

Background

In 3D prints, can often produce some waste material, if not carry out recovery processing to these materials, can cause the pollution to the environment, traditional plastics recovery plant function is single, and area is big, and the overall arrangement is not concentrated, and the jam takes place easily between the equipment incoherently each other, so designed this kind of 3D and printed plastic substrate recovery processing equipment.

Disclosure of Invention

The invention mainly solves the technical problem of providing 3D printing plastic substrate recovery processing equipment, wherein the equipment can store plastic substrates, can feed materials, can prevent material blockage, can ensure power transmission, and can stir and crush plastic.

In order to solve the technical problem, the invention relates to a plastic processing device, and particularly relates to a 3D printing plastic substrate recovery processing device which comprises a rotary material storage mechanism, a feeding shell mechanism and a crushing mechanism.

The rotary material storing mechanism is connected with the feeding shell mechanism, and the feeding shell mechanism is connected with the stirring mechanism.

As a further optimization of the technical scheme, the rotary material storage mechanism of the 3D printing plastic substrate recovery processing equipment comprises a rotary hopper mechanism, a reciprocating rack mechanism and a driving mechanism, wherein the rotary hopper mechanism is connected with the reciprocating rack mechanism, and the reciprocating rack mechanism is connected with the driving mechanism; the rotary bucket mechanism comprises a rotary bucket body, a through groove, a shaft and a gear, wherein the through groove is formed in the rotary bucket body, the shaft is connected with the rotary bucket body, and the gear is connected with the shaft; the reciprocating rack mechanism comprises a step slide rod and bilateral racks, the step slide rod is connected with the bilateral racks, and the bilateral racks are meshed with the gear; the driving mechanism comprises a door-shaped support, a gear I, a connecting shaft, a coupler and a driving servo motor, the door-shaped support is connected with the connecting shaft through a bearing, the connecting shaft is connected with the gear I, the gear I is meshed with racks on two sides, the connecting shaft is connected with the driving servo motor through the coupler, and the driving servo motor is connected with the door-shaped support.

As a further optimization of the technical scheme, the feeding shell mechanism of the 3D printing plastic substrate recovery processing equipment comprises a machine body mechanism, a vibration mechanism, a tensioning mechanism and a flexible hose, wherein the machine body mechanism is connected with the vibration mechanism, the tensioning mechanism is connected with the machine body mechanism, the tensioning mechanism is connected with the vibration mechanism, and the flexible hose is connected with the machine body mechanism; the fuselage mechanism comprises a strip plate, a vertical slide bar, a vibration spring, a connecting seat, a bearing seat I, a sliding seat, a fuselage body, a feeding port, a discharging port, the strip plate is connected with the vertical slide bar, the vertical slide bar is connected with the connecting seat, the vibration spring is sleeved on the vertical slide bar, the bearing seat is connected with the fuselage body, the connecting seat is connected with the fuselage body, the bearing seat I is connected with the fuselage body, the sliding seat is connected with the fuselage body, the feeding port is arranged on the fuselage body, the discharging port is communicated with the feeding port, the fuselage body is connected with a telescopic hose; the vibration mechanism comprises a connecting shaft I, an eccentric block, a belt pulley I, a belt, a motor belt pulley and a motor I, wherein the connecting shaft I is connected with the eccentric block, the connecting shaft I is connected with the belt pulley I, the belt pulley I is connected with the belt, the belt is connected with the motor belt pulley, the motor belt pulley is connected with the motor I, the connecting shaft I is connected with a bearing seat I in a bearing mode, and the motor I is connected with the machine body; straining device includes the articulated piece of band-pass hole, the take-up pulley, support I, ladder cooperation pole, the tensioning spring, go up and support, the tensioning axle, the articulated piece of band-pass hole is articulated mutually with supporting I, the take-up pulley is connected for the bearing with the connected mode that supports I, ladder cooperation pole and the articulated piece sliding connection of band-pass hole, the tensioning spring housing is on ladder cooperation pole, tensioning spring one end is supported on last support, the other end supports on the articulated piece of band-pass hole, ladder cooperation pole links to each other with last support, it links to each other with the tensioning axle to support I, the tensioning axle is connected for the bearing with the connected mode of fuselage body, it links to each other with the fuselage body.

As a further optimization of the technical scheme, the stirring mechanism of the 3D printing plastic substrate recovery processing equipment comprises a stirring shell mechanism, a stirring knife mechanism, a finished product hopper mechanism and a sliding door mechanism, wherein the stirring shell is connected with the stirring knife mechanism, the finished product hopper mechanism is connected with the stirring knife mechanism, and the sliding door mechanism is connected with the finished product hopper mechanism; the stirring and crushing shell mechanism comprises a stirring and crushing shell body, a vibration seat, an upper inlet, a stirring and crushing bearing seat and a lower outlet, the stirring and crushing shell body is connected with the vibration seat, the vibration seat is connected with a vertical sliding rod in a sliding mode, a vibration spring abuts against the vibration seat, the upper inlet is formed in a top plate of the stirring and crushing shell body, the lower outlet is formed in a bottom plate of the stirring and crushing shell body, and a flexible hose is connected with the stirring and crushing shell body; the stirring cutter mechanism comprises a stirring cutter wheel, a stirring cutter wheel shaft, a stirring coupler and a stirring driving motor, the stirring cutter wheel is connected with the stirring cutter wheel shaft, the stirring cutter wheel shaft is connected with the stirring driving motor through the stirring coupler, the stirring cutter wheel shaft is connected with the stirring bearing seat in a bearing connection mode, and the stirring driving motor is connected with the stirring shell body; the finished product hopper mechanism comprises a finished product hopper body, supporting legs and a stepped groove, the finished product hopper body is connected with the supporting legs, the finished product hopper body is connected with the stirring and crushing machine shell body, the supporting legs are connected with the stirring and crushing machine shell body, and the stepped groove is formed in the finished product hopper body; the sliding door mechanism comprises a sliding door with a stepped sliding block and a handle, the sliding door with the stepped sliding block is connected with the handle, and the sliding door with the stepped sliding block is matched with the stepped groove.

As a further optimization of the technical scheme, the mouth of the finished product hopper body of the 3D printing plastic substrate recovery processing equipment is communicated with the lower outlet.

As further optimization of the technical scheme, the material of the mincing knife wheel of the 3D printing plastic substrate recovery processing equipment is stainless steel.

As a further optimization of the technical scheme, the finished product hopper body of the 3D printing plastic substrate recovery processing equipment is made of high manganese steel.

The 3D printing plastic substrate recovery processing equipment has the beneficial effects that:

according to the 3D printing plastic substrate recovery processing equipment, the plastic substrate can be stored, the equipment can feed, the equipment can prevent material blockage, the equipment can ensure power transmission, and the equipment can stir and crush plastic.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

Fig. 1 is a schematic sectional structure diagram of a 3D printing plastic substrate recycling device according to the present invention.

Fig. 2 is a schematic structural diagram of a 3D printing plastic substrate recycling device of the present invention.

Fig. 3 is a schematic view of a supplementary structure of the 3D printing plastic substrate recycling device of the present invention.

Fig. 4 is a schematic structural diagram of a rotary material storage mechanism 1 of a 3D printing plastic substrate recycling device according to the present invention.

Fig. 5 is a schematic structural diagram of a rotating hopper mechanism 1-1 of the 3D printing plastic substrate recycling device of the invention.

Fig. 6 is a schematic structural diagram of a reciprocating rack mechanism 1-2 of the 3D printing plastic substrate recycling device of the invention.

Fig. 7 is a schematic structural diagram of a driving mechanism 1-3 of a 3D printing plastic substrate recycling device of the invention.

Fig. 8 is a schematic structural diagram of a feeding housing mechanism 2 of a 3D printing plastic substrate recycling device according to the present invention.

Fig. 9 is a supplementary structural schematic diagram of a feeding housing mechanism 2 of a 3D printing plastic substrate recycling device according to the present invention.

Fig. 10 is a schematic structural diagram of a machine body mechanism 2-1 of the 3D printing plastic substrate recycling equipment of the invention.

Fig. 11 is a supplementary structure diagram of the machine body mechanism 2-1 of the 3D printing plastic substrate recycling equipment of the invention.

Fig. 12 is a schematic structural diagram of a vibration mechanism 2-2 of the 3D printing plastic substrate recycling equipment according to the present invention.

Fig. 13 is a schematic structural diagram of a tensioning mechanism 2-3 of the 3D printing plastic substrate recycling device of the invention.

Fig. 14 is a schematic structural diagram of a mincing mechanism 3 of a 3D printing plastic substrate recycling device according to the invention.

FIG. 15 is a schematic structural diagram of a mincing machine shell mechanism 3-1 of the 3D printing plastic substrate recycling device of the invention.

FIG. 16 is a schematic plane structure diagram of a mincing machine shell mechanism 3-1 of the 3D printing plastic substrate recycling device of the invention.

Fig. 17 is a schematic structural diagram of a mincing knife mechanism 3-2 of the 3D printing plastic substrate recycling device of the invention.

Fig. 18 is a schematic structural diagram of a finished product hopper mechanism 3-3 of the 3D printing plastic substrate recycling processing equipment of the invention.

Fig. 19 is a schematic structural diagram of a sliding door mechanism 3-4 of the 3D printing plastic substrate recycling device of the invention.

In the figure: rotating the material storage mechanism 1; a rotating hopper mechanism 1-1; rotating the bucket body 1-1-1; a through groove 1-1-2; shaft 1-1-3; gears 1-1-4; a reciprocating rack mechanism 1-2; 1-2-1 of a stepped slide bar; a bilateral rack 1-2-2; a drive mechanism 1-3; 1-3-1 of a door type support; gear I1-3-2; connecting shafts 1-3-3; 1-3-4 of a coupler; driving a servo motor 1-3-5; a feeding shell mechanism 2; a body mechanism 2-1; 2-1-1 of a strip plate; a vertical slide bar 2-1-2; 2-1-3 of a vibration spring; 2-1-4 of a connecting seat; 2-1-5 of a bearing seat; bearing seats I2-1-6; 2-1-7 of a sliding seat; 2-1-8 of a machine body; 2-1-9 parts of a feed inlet; 2-1-10 parts of a discharge port; a vibration mechanism 2-2; connecting shaft I2-2-1; 2-2-2 of an eccentric block; pulley I2-2-3; 2-2-4 of a belt; 2-2-5 of a motor belt pulley; motor I2-2-6; 2-3 of a tensioning mechanism; the hinge block 2-3-1 with the through hole; 2-3-2 of a tensioning pulley; support I2-3-3; 2-3-4 of a step matching rod; 2-3-5 parts of a tension spring; 2-3-6 of upper support; 2-3-7 parts of a tensioning shaft; 2-4 parts of a flexible hose; a crushing mechanism 3; a pulper housing mechanism 3-1; a crushing casing body 3-1-1; a vibration seat 3-1-2; an upper inlet 3-1-3; crushing 3-1-4 parts of a bearing seat; a lower outlet 3-1-5; a mincing knife mechanism 3-2; 3-2-1 of a mincing knife wheel; a mincing knife wheel shaft 3-2-2; crushing the coupler 3-2-3; 3-2-4 parts of a stirring driving motor; a finished product hopper mechanism 3-3; 3-3-1 of a finished product hopper body; 3-3-2 of supporting legs; 3-3-3 parts of a stepped groove; 3-4 of a sliding door mechanism; a sliding door 3-4-1 with a step sliding block; 3-4-2 of a handle.

Detailed Description

The first embodiment is as follows:

the present embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, fig. 18, and fig. 19, and the present invention relates to a plastic processing apparatus, and more specifically, to a 3D printing plastic substrate recycling processing apparatus, which includes a rotary stock mechanism 1, a feed housing mechanism 2, and a mincing mechanism 3, and is capable of storing plastic substrates, feeding, preventing material blockage, ensuring power transmission, and mincing plastic.

The rotary material storing mechanism 1 is connected with the feeding shell mechanism 2, and the feeding shell mechanism 2 is connected with the stirring mechanism 3.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, fig. 18, and fig. 19, and the embodiment further describes the embodiment, where the rotary material storing mechanism 1 includes a rotary hopper mechanism 1-1, a reciprocating rack mechanism 1-2, and a driving mechanism 1-3, the rotary hopper mechanism 1-1 is connected to the reciprocating rack mechanism 1-2, and the reciprocating rack mechanism 1-2 is connected to the driving mechanism 1-3; the rotating bucket mechanism 1-1 comprises a rotating bucket body 1-1-1, a through groove 1-1-2, a shaft 1-1-3 and a gear 1-1-4, wherein the through groove 1-1-2 is formed in the rotating bucket body 1-1-1, the shaft 1-1-3 is connected with the rotating bucket body 1-1-1, and the gear 1-1-4 is connected with the shaft 1-1-3; the reciprocating rack mechanism 1-2 comprises a step slide bar 1-2-1 and bilateral racks 1-2-2, the step slide bar 1-2-1 is connected with the bilateral racks 1-2-2, and the bilateral racks 1-2-2 are meshed with gears 1-1-4; the driving mechanism 1-3 comprises a door-shaped support 1-3-1, a gear I1-3-2, a connecting shaft 1-3-3, a coupler 1-3-4 and a driving servo motor 1-3-5, the door-shaped support 1-3-1 is connected with the connecting shaft 1-3-3 through a bearing, the connecting shaft 1-3-3 is connected with the gear I1-3-2, the gear I1-3-2 is meshed with the bilateral rack 1-2-2, the connecting shaft 1-3-3 is connected with the driving servo motor 1-3-5 through the coupler 1-3-4, the driving servo motor 1-3-5 is connected with the door-shaped support 1-3-1, a base material is placed in the through groove 1-1-2 and then operates to drive the servo motor 1-3-5 to drive the shaft coupler 1-3-1 The device 1-3-4 rotates, the coupling 1-3-4 rotates to drive the connecting shaft 1-3-3 to rotate, the connecting shaft 1-3-3 rotates to drive the gear I1-3-2 to rotate, the gear I1-3-2 rotates to drive the gear 1-1-4 to rotate, the gear 1-1-4 rotates to drive the shaft 1-1-3 to rotate, the shaft 1-1-3 rotates to drive the rotating bucket body 1-1-1 to rotate, and the rotating bucket body 1-1-1 stops rotating to drive the servo motor 1-3-5 when rotating 90 degrees, so that the base material is stored in the through groove 1-1-2.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, fig. 18, and fig. 19, and the embodiment further describes the embodiment, wherein the feeding housing mechanism 2 includes a body mechanism 2-1, a vibrating mechanism 2-2, a tensioning mechanism 2-3, and a flexible hose 2-4, the body mechanism 2-1 is connected to the vibrating mechanism 2-2, the tensioning mechanism 2-3 is connected to the body mechanism 2-1, the tensioning mechanism 2-3 is connected to the vibrating mechanism 2-2, and the flexible hose 2-4 is connected to the body mechanism 2-1; the machine body mechanism 2-1 comprises a strip plate 2-1-1, a vertical slide bar 2-1-2, a vibration spring 2-1-3, a connecting seat 2-1-4, a bearing seat 2-1-5, a bearing seat I2-1-6, a slide seat 2-1-7, a machine body 2-1-8, a feeding port 2-1-9 and a discharging port 2-1-10, the strip plate 2-1-1 is connected with the vertical slide bar 2-1-2, the vertical slide bar 2-1-2 is connected with the connecting seat 2-1-4, the vibration spring 2-1-3 is sleeved on the vertical slide bar 2-1-2, the bearing seat 2-1-5 is connected with the machine body 2-1-8, the connecting seat 2-1-4 is connected with the machine body 2-1-8, the bearing seat I2-1-6 is connected with the machine body 2-1-8, the sliding seat 2-1-7 is connected with the machine body 2-1-8, the feeding port 2-1-9 is arranged on the machine body 2-1-8, the discharging port 2-1-10 is communicated with the feeding port 2-1-9, the machine body 2-1-8 is connected with the flexible hose 2-4, and the sliding seat 2-1-7 is matched with the stepped sliding rod 1-2-1; the vibration mechanism 2-2 comprises a connecting shaft I2-2-1, an eccentric block 2-2-2, a belt pulley I2-2-3, a belt 2-2-4, a motor belt pulley 2-2-5 and a motor I2-2-6, the connecting shaft I2-2-1 is connected with the eccentric block 2-2-2, the connecting shaft I2-2-1 is connected with the belt pulley I2-2-3, the belt pulley I2-2-3 is connected with the belt 2-2-4, the belt 2-2-4 is connected with the motor belt pulley 2-2-5, the motor belt pulley 2-2-5 is connected with the motor I2-2-6, the connecting mode of the connecting shaft I2-2-1 and a bearing seat I2-1-6 is bearing connection, the motor I2-2-6 is connected with the machine body 2-1-8, the motor I2-2-6 operates to drive the motor belt pulley 2-2-5 to rotate, the motor belt pulley 2-2-5 rotates to drive the belt pulley I2-2-3 to rotate through the belt 2-2-4, the belt pulley I2-2-3 rotates to drive the connecting shaft I2-2-1 to rotate, the connecting shaft I2-2-1 rotates to drive the eccentric block 2-2-2 to rotate, the eccentric block 2-2-2 rotates to form a bias vibration force, the machine body 2-1-8 moves downwards under the drive of the bias vibration force, the vibration spring 2-1-3 is compressed when the machine body 2-1-8 moves downwards, then the base material moves upwards under the drive of the rebound action of the vibration spring 2-1-3 and the upward bias force, so that the machine body 2-1-8 can vibrate continuously, and the base material which is carelessly clamped can be vibrated; the tensioning mechanism 2-3 comprises a hinge block 2-3-1 with a through hole, a tensioning belt pulley 2-3-2, a support I2-3-3, a step fit rod 2-3-4, a tensioning spring 2-3-5, an upper support 2-3-6 and a tensioning shaft 2-3-7, the hinge block 2-3-1 with the through hole is hinged with the support I2-3-3, the tensioning belt pulley 2-3-2 is connected with the support I2-3-3 in a bearing mode, the step fit rod 2-3-4 is connected with the hinge block 2-3-1 with the through hole in a sliding mode, the tensioning spring 2-3-5 is sleeved on the step fit rod 2-3-4, one end of the tensioning spring 2-3-5 is abutted against the upper support 2-3-6, the other end of the ladder matching rod is supported on a hinge block 2-3-1 with a through hole, a ladder matching rod 2-3-4 is connected with an upper support 2-3-6, a support I2-3-3 is connected with a tension shaft 2-3-7, the tension shaft 2-3-7 is connected with a machine body 2-1-8 in a bearing mode, the upper support 2-3-6 is connected with the machine body 2-1-8, a certain pre-tightening force is ensured when the tension spring 2-3-5 is installed, so that the tension spring 2-3-5 has a rebound tendency, the rebound tendency can push the support I2-3-3, the support I2-3-3 has a downward movement tendency, the support I2-3-3 can transmit the downward movement tendency to a tension pulley 2-3-2, therefore, the tensioning pulley 2-3-2 is always pressed on the belt 2-2-4 to prevent the belt 2-2-4 from slipping, so that the power output of the motor I2-2-6 can be ensured.

The fourth concrete implementation mode:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, fig. 18, and fig. 19, and the embodiment further describes the first embodiment, wherein the mincing mechanism 3 comprises a mincing machine shell mechanism 3-1, a mincing knife mechanism 3-2, a finished product hopper mechanism 3-3, and a sliding door mechanism 3-4, the mincing machine shell 3-1 is connected with the mincing knife mechanism 3-2, the finished product hopper mechanism 3-3 is connected with the mincing knife mechanism 3-2, and the sliding door mechanism 3-4 is connected with the finished product hopper mechanism 3-3; the stirring and crushing machine shell mechanism 3-1 comprises a stirring and crushing machine shell body 3-1-1, a vibration seat 3-1-2, an upper inlet 3-1-3, a stirring and crushing bearing seat 3-1-4 and a lower outlet 3-1-5, the stirring and crushing machine shell body 3-1-1 is connected with the vibration seat 3-1-2, the vibration seat 3-1-2 is connected with a vertical sliding rod 2-1-2 in a sliding way, a vibration spring 2-1-3 is abutted against the vibration seat 3-1-2, the upper inlet 3-1-3 is opened on a top plate of the stirring and crushing machine shell body 3-1-1, the lower outlet 3-1-5 is opened on a bottom plate of the stirring and crushing machine shell body 3-1-1, a flexible pipe 2-4 is connected with the stirring and crushing machine shell body 3-1-1, when the feeding function is needed, the feeding device can rotate forward and backward alternately to drive the servo motors 1-3-5, the servo motors 1-3-5 are driven to drive the couplers 1-3-4 to rotate in a reciprocating manner, the couplers 1-3-4 are driven to rotate in a reciprocating manner to drive the connecting shafts 1-3-3 to rotate in a reciprocating manner, the connecting shafts 1-3-3 are driven to rotate in a reciprocating manner to drive the gears I1-3-2 to rotate in a reciprocating manner, the gears I1-3-2 are driven to rotate in a reciprocating manner to drive the gears 1-1-4 to rotate in a reciprocating manner, the gears 1-1-4 are driven to rotate in a reciprocating manner to drive the rotating buckets 1-1-1 to rotate in a reciprocating manner, thus, the base material in the through groove 1-1-2 can move along with the reciprocating rotation of the rotating bucket body 1-1-1, and the base material can smoothly enter the mincing machine shell body 3-1-1 through the flexible hose 2-4 and the upper inlet 3-1-3; the stirring cutter mechanism 3-2 comprises a stirring cutter wheel 3-2-1, a stirring cutter wheel shaft 3-2-2, a stirring coupler 3-2-3 and a stirring driving motor 3-2-4, wherein the stirring cutter wheel 3-2-1 is connected with the stirring cutter wheel shaft 3-2-2, the stirring cutter wheel shaft 3-2-2 is connected with the stirring driving motor 3-2-4 through the stirring coupler 3-2-3, the stirring cutter wheel shaft 3-2-2 is connected with the stirring bearing seat 3-1-4 through a bearing, and the stirring driving motor 3-2-4 is connected with the stirring machine shell body 3-1-1; the finished product hopper mechanism 3-3 comprises a finished product hopper body 3-3-1, supporting legs 3-3-2 and a stepped groove 3-3-3, wherein the finished product hopper body 3-3-1 is connected with the supporting legs 3-3-2, the finished product hopper body 3-3-1 is connected with the mincing machine shell body 3-1-1, the supporting legs 3-3-2 are connected with the mincing machine shell body 3-1-1, and the stepped groove 3-3-3 is arranged on the finished product hopper body 3-3-1; the sliding door mechanism 3-4 comprises a sliding door with a stepped sliding block 3-4-1 and a handle 3-4-2, the sliding door with the stepped sliding block 3-4-1 is connected with the handle 3-4-2, the sliding door with the stepped sliding block 3-4-1 is matched with a stepped groove 3-3-3, a stirring and crushing coupler 3-2-3 is driven to rotate by the operation of a stirring and crushing driving motor 3-2-4, the stirring and crushing coupler 3-2-3 drives a stirring and crushing cutter wheel shaft 3-2-2 to rotate, the stirring and crushing cutter wheel shaft 3-2-2 drives a stirring and crushing cutter wheel 3-2-1 to rotate, the stirring and crushing cutter wheel 3-2-1 rotates to stir base materials entering from an upper inlet 3-1-3, the crushed plastic can fall from the lower outlet 3-1-5 and then enter the finished product hopper body 3-3-1, when the crushed base material is fully accumulated in the finished product hopper body 3-3-1, the handle 3-4-2 can be pulled, and the handle 3-4-2 can drive the sliding door with the stepped slide block 3-4-1 to be separated from the stepped groove 3-3-3, so that the crushed base material can be poured out.

The fifth concrete implementation mode:

the present embodiment will be described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, fig. 18, and fig. 19, and the present embodiment further describes a first embodiment in which the mouth of the finished product hopper body 3-3-1 communicates with the lower outlet 3-1-5.

The sixth specific implementation mode:

the present embodiment will be described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, fig. 18, and fig. 19, and the first embodiment will be further described in the present embodiment, in which the material of the mincing knife wheel 3-2-1 is stainless steel.

The seventh embodiment:

the present embodiment will be described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, and 19, and the present embodiment further describes a first embodiment in which the material of the finished hopper body 3-3-1 is high manganese steel.

The working principle of the device is as follows: the equipment can store plastic base materials, the base materials are placed in the through groove 1-1-2 and then operate to drive the servo motor 1-3-5 to drive the coupler 1-3-4 to rotate, the coupler 1-3-4 rotates to drive the connecting shaft 1-3-3 to rotate, the connecting shaft 1-3-3 rotates to drive the gear I1-3-2 to rotate, the gear I1-3-2 rotates to drive the gear 1-1-4 to rotate, the gear 1-1-4 rotates to drive the shaft 1-1-3 to rotate, the shaft 1-1-3 rotates to drive the rotating bucket body 1-1-1 to rotate, the rotating bucket body 1-1-1 stops operating to drive the servo motor 1-3-5 when rotating 90 degrees, this leaves the substrate in the through slot 1-1-2; the device can carry out feeding, when a feeding function is needed, the device can alternately rotate in the forward direction and the reverse direction to drive the servo motor 1-3-5, the servo motor 1-3-5 is driven to drive the coupler 1-3-4 to rotate in a reciprocating manner, the coupler 1-3-4 is driven to rotate in a reciprocating manner to drive the connecting shaft 1-3-3 to rotate in a reciprocating manner, the connecting shaft 1-3-3 rotates in a reciprocating manner to drive the gear I1-3-2 to rotate in a reciprocating manner, the gear I1-3-2 rotates in a reciprocating manner to drive the gear 1-1-4 to rotate in a reciprocating manner, the gear 1-1-4 rotates in a reciprocating manner to drive the shaft 1-1-3 to rotate in a reciprocating manner, and the shaft 1-1-3 rotates in a reciprocating manner to drive the rotating bucket body 1-1-1, thus, the base material in the through groove 1-1-2 can move along with the reciprocating rotation of the rotating bucket body 1-1-1, and the base material can smoothly enter the mincing machine shell body 3-1-1 through the flexible hose 2-4 and the upper inlet 3-1-3; the device can prevent material blockage, the motor pulley 2-2-5 is driven to rotate by the operation of the motor I2-2-6, the motor pulley 2-2-5 rotates to drive the pulley I2-2-3 to rotate by the belt 2-2-4, the pulley I2-2-3 rotates to drive the connecting shaft I2-2-1 to rotate, the connecting shaft I2-2-1 rotates to drive the eccentric block 2-2-2 to rotate, the eccentric block 2-2-2 rotates to form a bias vibration force, the machine body 2-1-8 moves downwards under the drive of the bias vibration force, and the vibration spring 2-1-3 is compressed when the machine body 2-1-8 moves downwards, then the base material moves upwards under the drive of the rebound action of the vibration spring 2-1-3 and the upward bias force, so that the machine body 2-1-8 can vibrate continuously, and the base material which is carelessly clamped can be vibrated; the device can ensure power transmission, certain pre-tightening force is ensured when the tension spring 2-3-5 is installed, so that the tension spring 2-3-5 has a rebound tendency, the rebound tendency can push the support I2-3-3, the support I2-3-3 has a downward movement tendency, the support I2-3-3 can transmit the downward movement tendency to the tension pulley 2-3-2, the tension pulley 2-3-2 can be always pressed on the belt 2-2-4, the belt 2-2-4 is prevented from slipping, and the power output of the motor I2-2-6 can be ensured; the equipment can stir plastics, the stirring coupler 3-2-3 is driven to rotate by the operation of a stirring driving motor 3-2-4, the stirring coupler 3-2-3 rotates to drive a stirring cutter wheel shaft 3-2-2 to rotate, the stirring cutter wheel shaft 3-2-2 rotates to drive a stirring cutter wheel 3-2-1 to rotate, the stirring cutter wheel 3-2-1 rotates to stir the base material entering from an upper inlet 3-1-3, the stirred plastics can fall from a lower outlet 3-1-5 and then enter a finished product hopper body 3-3-1, and a handle 3-4-2 can be pulled after the crushed base material is fully accumulated in the finished product hopper body 3-3-1, the handle 3-4-2 can drive the sliding door 3-4-1 with the step slide block to be separated from the step groove 3-3-3, so that the crushed base material can be poured out.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (4)

1. The utility model provides a 3D prints plastic substrate recovery processing equipment, includes rotation stock mechanism (1), feed shell mechanism (2), pulper mechanism (3), its characterized in that: the rotary material storing mechanism (1) comprises a rotary hopper mechanism (1-1), a reciprocating rack mechanism (1-2) and a driving mechanism (1-3), wherein the rotary hopper mechanism (1-1) is connected with the reciprocating rack mechanism (1-2), and the reciprocating rack mechanism (1-2) is connected with the driving mechanism (1-3); the rotary bucket mechanism (1-1) comprises a rotary bucket body (1-1-1), a through groove (1-1-2), a shaft (1-1-3) and a gear (1-1-4), wherein the through groove (1-1-2) is formed in the rotary bucket body (1-1-1), the shaft (1-1-3) is connected with the rotary bucket body (1-1-1), and the gear (1-1-4) is connected with the shaft (1-1-3); the reciprocating rack mechanism (1-2) comprises a step sliding rod (1-2-1) and bilateral racks (1-2-2), the step sliding rod (1-2-1) is connected with the bilateral racks (1-2-2), and the bilateral racks (1-2-2) are meshed with the gears (1-1-4); the driving mechanism (1-3) comprises a door-shaped support (1-3-1), a gear I (1-3-2) and a connecting shaft (1-3-3), the connecting mechanism comprises a coupler (1-3-4) and a driving servo motor (1-3-5), wherein a door-shaped support (1-3-1) is connected with a connecting shaft (1-3-3) in a bearing mode, the connecting shaft (1-3-3) is connected with a gear I (1-3-2), the gear I (1-3-2) is meshed with a rack (1-2-2) on two sides, the connecting shaft (1-3-3) is connected with the driving servo motor (1-3-5) through the coupler (1-3-4), and the driving servo motor (1-3-5) is connected with the door-shaped support (1-3-1);

the feeding shell mechanism (2) comprises a machine body mechanism (2-1), a vibration mechanism (2-2), a tensioning mechanism (2-3) and a flexible hose (2-4), wherein the machine body mechanism (2-1) is connected with the vibration mechanism (2-2), the tensioning mechanism (2-3) is connected with the machine body mechanism (2-1), the tensioning mechanism (2-3) is connected with the vibration mechanism (2-2), and the flexible hose (2-4) is connected with the machine body mechanism (2-1); the machine body mechanism (2-1) comprises a strip plate (2-1-1), a vertical slide rod (2-1-2), a vibration spring (2-1-3), a connecting seat (2-1-4), a bearing seat (2-1-5), a bearing seat I (2-1-6), a slide seat (2-1-7), a machine body (2-1-8), a feeding hole (2-1-9) and a discharging hole (2-1-10), the strip plate (2-1-1) is connected with the vertical slide rod (2-1-2), the vertical slide rod (2-1-2) is connected with the connecting seat (2-1-4), the vibration spring (2-1-3) is sleeved on the vertical slide rod (2-1-2), the bearing seat (2-1-5) is connected with the machine body (2-1-8), the connecting seat (2-1-4) is connected with the machine body (2-1-8), the bearing seat I (2-1-6) is connected with the machine body (2-1-8), the sliding seat (2-1-7) is connected with the machine body (2-1-8), the feeding port (2-1-9) is arranged on the machine body (2-1-8), the discharging port (2-1-10) is communicated with the feeding port (2-1-9), the machine body (2-1-8) is connected with the telescopic hose (2-4), the sliding seat (2-1-7) is matched with the stepped sliding rod (1-2-1); the vibration mechanism (2-2) comprises a connecting shaft I (2-2-1), an eccentric block (2-2-2), a belt pulley I (2-2-3), a belt (2-2-4), a motor belt pulley (2-2-5) and a motor I (2-2-6), the connecting shaft I (2-2-1) is connected with the eccentric block (2-2-2), the connecting shaft I (2-2-1) is connected with the belt pulley I (2-2-3), the belt pulley I (2-2-3) is connected with the belt (2-2-4), the belt (2-2-4) is connected with the motor belt pulley (2-2-5), the motor belt pulley (2-2-5) is connected with the motor I (2-2-6), the connecting shaft I (2-2-1) is connected with the bearing seat I (2-1-6) in a bearing connection mode, and the motor I (2-2-6) is connected with the machine body (2-1-8); the tensioning mechanism (2-3) comprises a through hole hinge block (2-3-1), a tensioning belt pulley (2-3-2), a support I (2-3-3), a step fit rod (2-3-4), a tensioning spring (2-3-5), an upper support (2-3-6) and a tensioning shaft (2-3-7), the through hole hinge block (2-3-1) is hinged with the support I (2-3-3), the tensioning belt pulley (2-3-2) is connected with the support I (2-3-3) in a bearing manner, the step fit rod (2-3-4) is connected with the through hole hinge block (2-3-1) in a sliding manner, the tensioning spring (2-3-5) is sleeved on the step fit rod (2-3-4), one end of a tension spring (2-3-5) abuts against the upper support (2-3-6), the other end of the tension spring abuts against the hinge block (2-3-1) with the through hole, the step matching rod (2-3-4) is connected with the upper support (2-3-6), the support I (2-3-3) is connected with a tension shaft (2-3-7), the tension shaft (2-3-7) is connected with the machine body (2-1-8) in a bearing mode, and the upper support (2-3-6) is connected with the machine body (2-1-8);

the stirring mechanism (3) comprises a stirring machine shell mechanism (3-1), a stirring knife mechanism (3-2), a finished product hopper mechanism (3-3) and a sliding door mechanism (3-4), the stirring machine shell (3-1) is connected with the stirring knife mechanism (3-2), the finished product hopper mechanism (3-3) is connected with the stirring knife mechanism (3-2), and the sliding door mechanism (3-4) is connected with the finished product hopper mechanism (3-3); the stirring and crushing machine shell mechanism (3-1) comprises a stirring and crushing machine shell body (3-1-1), a vibration seat (3-1-2), an upper inlet (3-1-3), a stirring and crushing bearing seat (3-1-4) and a lower outlet (3-1-5), the stirring and crushing machine shell body (3-1-1) is connected with the vibration seat (3-1-2), the vibration seat (3-1-2) is connected with a vertical sliding rod (2-1-2) in a sliding way, a vibration spring (2-1-3) is propped against the vibration seat (3-1-2), the upper inlet (3-1-3) is opened on a top plate of the stirring and crushing machine shell body (3-1-1), the lower outlet (3-1-5) is opened on a bottom plate of the stirring and crushing machine shell body (3-1-1), the flexible hose (2-4) is connected with the mincing machine shell body (3-1-1); the stirring cutter mechanism (3-2) comprises a stirring cutter wheel (3-2-1), a stirring cutter wheel shaft (3-2-2), a stirring coupler (3-2-3) and a stirring driving motor (3-2-4), the stirring cutter wheel (3-2-1) is connected with the stirring cutter wheel shaft (3-2-2), the stirring cutter wheel shaft (3-2-2) is connected with the stirring driving motor (3-2-4) through the stirring coupler (3-2-3), the stirring cutter wheel shaft (3-2-2) is connected with the stirring bearing seat (3-1-4) in a bearing mode, and the stirring driving motor (3-2-4) is connected with the stirring shell body (3-1-1); the finished product hopper mechanism (3-3) comprises a finished product hopper body (3-3-1), supporting legs (3-3-2) and a stepped groove (3-3-3), the finished product hopper body (3-3-1) is connected with the supporting legs (3-3-2), the finished product hopper body (3-3-1) is connected with the mincing machine shell body (3-1-1), the supporting legs (3-3-2) are connected with the mincing machine shell body (3-1-1), and the stepped groove (3-3-3) is formed in the finished product hopper body (3-3-1); the sliding door mechanism (3-4) comprises a sliding door with a stepped sliding block (3-4-1) and a handle (3-4-2), the sliding door with the stepped sliding block (3-4-1) is connected with the handle (3-4-2), and the sliding door with the stepped sliding block (3-4-1) is matched with the stepped groove (3-3-3);

the rotary material storing mechanism (1) is connected with the feeding shell mechanism (2), and the feeding shell mechanism (2) is connected with the crushing mechanism (3).

2. The 3D printing plastic substrate recycling device according to claim 1, wherein: the mouth of the finished product hopper body (3-3-1) is communicated with the lower outlet (3-1-5).

3. The 3D printing plastic substrate recycling device according to claim 1, wherein: the material of the mincing knife wheel (3-2-1) is stainless steel.

4. The 3D printing plastic substrate recycling device according to claim 1, wherein: the finished product hopper body (3-3-1) is made of high manganese steel.

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