LT6666B - Dual-caliber nozzel of 3d printer - Google Patents

Abstract

The present invention discloses a dual-caliber nozzel of 3D printer comprising an extruding outlet outer wall and a discharging tube; the extruding outlet outer wall being tapered and provided with an inner cavity located on the same axis as the extruding outlet outer wall; the discharging tube being able to inject molten consumables to the inner cavity of the extruding outlet outer wall; the lower side wall of the discharging tube being circumferentially provided with a plurality of evenly-spaced discharging holes; the lower end of the discharging tube being connected with a control mechanism contained in a cavity formed by the annular sealing block and the extruding outlet outer wall; the control mechanism comprising a limited block coaxially connected to the lower end of the discharging tube and being in the shape of two coaxial circular truncated cones; from top circular truncated cone to bottom circular truncated cone, the radius of the limited block gradually increasing at first and then gradually decreasing; the limited block is provided with a plurality of first material-guiding holes and second material-guiding holes; the first material-guiding holes being in communication with the discharging holes disposed at the lower end of the discharging tube via the cavity formed by the annular sealing block and the extruding outlet outer wall.

Description

Technical field

The present invention relates to a 3D printer extrusion outlet, and more particularly to a 3D printer extrusion outlet with two sizes, gauges, and variable flow.

State of the art

The 3D printer uses cumulative production technology, i.e. y. fast forming technology; which is based on a digital model and produces a 3D object by printing layers of adhesive such as special wax material, metal powder or plastic. An existing 3D printer molds and manufactures products layer by layer for printing.

Patent CN 201711362000.6 (Published 13/07/2018) discloses a multi-injector 3D printer spray head having a spindle that can rotate about a spindle, a rotatable disc that can rotate relative to an outlet cylinder; a plurality of nozzles arranged in a rotational direction at the bottom of the outlet cylinder; the internal diameters of the through-holes are different for all nozzles; the discharge cylinder is provided with a plurality of transport channels, respectively, connected to each of the spray passages; a rotating plate at the upper end of the outlet cylinder and having an orifice, wherein any one of the transport channels and the interior of the respective nozzle forms a printing channel. Multiple sprinklers are mounted on the lower end of the drain cylinder; all nozzles have different diameters of internal openings; the drain cylinder is rotated only when changing guns; the appropriate sprayer is adapted to the printing position; and, at the same time, the position of the orifice is adjusted by rotating the rotating plate to form a printing channel that meets the transition needs of the spray printing process. Although the diameter of the nozzle head can be varied in the present invention, the benefit is achieved by having a plurality of nozzles of different diameters.

Patent CN 201810420528.2 (published July 24, 2018) discloses a new 3D printer sprinkler mechanism comprising a frame, a feed tube, a small ball valve, a condensation tube and a heating head, wherein the frame is provided with a feed tube through a mounting groove, through a connecting head is in threaded connection with small ball valve threaded connection, threaded connection is on top and bottom of small ball valve, junction tube is positioned on the bottom of small ball valve and upper end of junction tube is fixed and enclosed with junction head with threaded connection ball valve, the supply pipe has a material channel, and the conduit is in the conduit, and the material channel is connected to the conduit, the heating head is disposed in an insertion manner at the bottom of the conduit, the frame is used to attach the conduit to loosen. The feed tube feeds the material into the condensation tube through the material passage and blocks the material supplied through the small ball valve, and it may be convenient to feed multiple supply tubes to feed the material to the heating head through the conduit. However, the present invention does not provide a variation in the diameter of the sprayer to meet different printing accuracy requirements.

The 3D printer extrusion outlet is used to extrude adhesive material into the work surface from the storage cavity, and most existing printers use a fixed size, caliber extrusion outlet and a fixed amount of adhesive extruded from the extrusion outlet over a period of time; the disadvantage of which is that the caliber of the extrusion outlet and the amount of extrusion cannot vary according to different printing accuracy needs, i.e. y. a fixed caliber cannot meet production precision demands when high precision is required, and a small amount of fixed caliber extrusion results in low print efficiency when low precision is required.

Description of the Invention

To solve the problem of existing technology, it is an object of the present invention to provide an extruder outlet for a 3D printer having two calibers and capable of switching between two different calibers without interrupting the printing process of the printer; moreover, the present invention can regulate the flow and the amount of extrusion per unit time at the extrusion outlet according to the actual printing needs.

Two-size, caliber 3D printer sprayer comprising extrusion outlet outer wall and outlet tube; the outer wall of the extrusion outlet is tapered and has an inner cavity located on the same axis as the outer wall of the extrusion outlet; the discharge tube may inject molten consumables into the inner cavity of the outer wall of the extrusion outlet; the lower sidewall of the outlet tube being circumferentially arranged with a plurality of evenly spaced outlets; the annular sealing unit is positioned above the outlets and in the same axis as the outlet tube; an annular sealing unit mounted on the upper portion of the inner cavity of the outer wall of the extrusion outlet to separate and move along the axis of the outer wall of the extrusion outlet; the lower end of the outlet tube being connected to a control mechanism located in a cavity formed through an annular sealing unit and an outer wall of the extrusion outlet; a control mechanism comprising a limited block coaxially connected to the lower end of the outlet tube in the form of two coaxial round cut cones; the radius of the bounded block of the upper circular cut cone to the lower round cut cone initially increases gradually and then gradually decreases; the constituent part of the circular cut cone on the lower part of the block being parallel to the constituent part of the outer wall of the extrusion outlet; the limited block has a plurality of material deflection openings including a plurality of deflection openings of the first material and deflection openings of the second material; the first material deflection apertures are disposed in a circular cut cone on the upper portion of the restricted block and are connected to the outlet apertures at the lower end of the outlet tube through a cavity formed by an annular sealing unit and an outer wall of the extrusion outlet; the second material deflection apertures are coaxially located at the bottom of the lower block's lower circular cut cone and are connected to the first material deflection apertures; the bottom of the outer wall of the extrusion outlet being provided with an extrusion outlet connected to the inner cavity of the outer wall of the extrusion outlet; the extrusion outlet is disposed on the same axis as the second material deflection apertures having a radius coinciding with the radius of the lower block of the lower circular cut cone; the diameter of the second material guide openings being smaller than the extrusion outlet diameter.

Optionally, the middle portion of the drain tube is provided with a guide mechanism, the guide end of the guide mechanism is connected to the output end of the drive mechanism and can control the movement of the drain tube in its axial direction; the guide mechanism may direct the outlet tube and pull the limited block and control its movement in the direction of the axis of the outer wall of the central extrusion outlet for effecting adjustment of the size of the outer wall opening of the extrusion outlet.

Optionally, the guide mechanism comprises switching units disposed on the outlet pipe wall; the switching units are arranged symmetrically in relation to the axis of the discharge pipe, and the axis of the switching units is distributed in the radial direction of the discharge pipe; the shifting units are connected to the output end of the actuator, which can push the shifting units, pull the discharge tube to move along its axis, and change the status of the lower block's lower circular cut cone and outer wall of the extrusion outlet from interconnection to separation, to the interconnection.

Optionally, the actuator includes a motor and a guide block; the end of the output shaft of the motor being connected to the guide block to control the movement of the guide block in a direction perpendicular to the central axis of the outlet pipe; the guide unit has a guide rail corresponding to the switching units mounted on the outlet pipe wall; turning the guide block capable of pushing the shifting blocks and pulling the drain tube so that it moves along the central axis; movement of the discharge tube capable of controlling the movement of the restricted block connected to the discharge tube in the direction of the discharge tube and adjusting the gap between the restricted block and the outer wall of the extrusion outlet.

The advantages of the present invention over the present technology are that the 3D printer extruder outlet with two caliber and variable flow can control the extrusion outlet radius and extrusion flow; turning the control unit is motor controlled; during the tilting process, the guide block shifts in the direction of the length of the first pulling groove relative to the outlet pipe; the movement of the drain tube along its axis controls the movement of the limited block connected to the drain tube from the outer wall; as a limited block away from the outer wall of the extrusion outlet, the extrusion radius will change from the second material outlet radius to the extrusion outlet outer wall extrusion outlet radius, thereby providing an increase in the extrusion radius and amount of extrusion.

Description of the drawings

In order to more clearly illustrate embodiments of the present invention, the drawings necessary for the embodiments will be briefly described and it will be apparent to those skilled in the art that these drawings are only a few embodiments of the invention and other drawings may be obtained.

Fig. is a schematic diagram of the general construction of the present invention.

Fig. is a diagram of the first part of the present invention.

Fig. is a diagram of the second part of the present invention.

Fig. is a schematic diagram of the material deflection mechanism of the present invention.

Fig. is a schematic diagram of the actuator of the present invention.

Fig. is a schematic diagram of the actuator of the present invention.

References in the drawings: 10. material guide, 11. outer wall of extrusion outlet, 12. outlet tube, 13. annular sealing unit, 14. limited block, 15. switching unit, 16. threaded coupling, 20. actuator, 21 . engine, 22. Guide unit, 30. heating mechanism, 40. holding mechanism.

Embodiments of the invention

Embodiments of the present invention will provide a clear and detailed description of the technical solution and it will be understood that the embodiments described are only a part of the embodiments of the present invention. All other embodiments obtained by the embodiments of the invention without the creative work of those skilled in the art are within the scope of the present invention.

According to Fig. 1. The extruder outlet of the 3D printer, with two gauges and variable flow, includes a material deflector 10, a drive mechanism 20, a heating mechanism 30 and a holding mechanism 40; the holding mechanism 40 has an internal cavity which is stored together with the consumables for printing the blank; the end of the outlet opening at the bottom of the holding mechanism 40 is connected to the bottom of the material inlet opening of the bottom of the guide means 10; the material deflecting mechanism 10 is used to extrude the consumables from the holding surfaces 40 to the printing surfaces below the end 10 of the material deflecting mechanism outlet; a heating mechanism 30 provided in the middle of the material deflecting mechanism 10 for supplying a heat source to dissolve the consumables; the material deflecting mechanism 10 further comprising a control mechanism and a deflection mechanism; the control mechanism is mounted at the bottom of the material guide mechanism and can be used to control the extrusion caliber and consumables extrusion flow; the guide mechanism is provided on the inside of the material guide mechanism 10, the guide end of the guide mechanism being connected to the end of the actuator outlet 20; the end of the actuator outlet 20 may control the guide end of the deflector to direct in the direction of deflection of the material.

Preferred consumables are any type or combination of adhesive plastic materials, photosensitive rubber, metal powder, ceramics, edible fats and oils.

Preferably, according to Figs. the material deflecting mechanism 10 having an extrusion outlet outer wall 11 and a discharge tube 12; the outer wall 11 of the extrusion outlet is conical and has an internal cavity located on the same axis as the outer wall 11 of the extrusion outlet; the outlet tube 12 is connected to the outlet end located at the bottom of the holding mechanism 40; the lower side wall of the outlet tube 12 being circumferentially arranged with a plurality of evenly spaced outlets; an annular sealing unit 13 located above the outlets, which is on the same axis as the outlet tube 12; the annular sealing unit 13 fits into the upper portion of the inner cavity of the extrusion outlet outer wall 11 for sealing and moving along the axis of the outlet wall 11; the lower end of the outlet tube 12 being connected to a control mechanism located in a cavity formed through an annular sealing unit 13 and an outer wall 11 of the extrusion outlet; the control mechanism comprises a limited block 14, coaxially connected to the lower end of the outlet pipe 12 and having the shape of two coaxial round cut cones; the radius from the upper circular cut cone to the lower circular cut cone 14 initially increasing gradually and then gradually decreasing; the constituent part of the circular cut cone in the lower part of the limited block 14 being parallel to the constituent part of the outer wall of the extrusion outlet; the limited block 14 has a plurality of material deflection openings including a plurality of deflection openings for the first material and the deflection openings for the second material; the first material deflection apertures being disposed with respect to the circular cut cone of the upper portion of the restricted unit 14 and aligned with the outlet apertures at the end of the lower outlet tube 12 through a cavity formed by an annular sealing unit 13 and an extruder outlet wall 11; the second material deflection apertures are coaxially disposed at the bottom of the lower circular cut cone of the bounding block 14 and are interconnected with the first material deflection apertures; the bottom of the outer wall 11 of the extrusion outlet being provided with an extrusion outlet connected to the outer wall 11 of the extrusion outlet; the extrusion outlet is on the same axis as the second material guide aperture and has a radius coinciding with the radius of the lower circular cut cone of the limited block 14; the second material having a diameter smaller than the extrusion orifice, the middle portion of the outlet tube 12 being guided, the guide portion of the guide portion being connected to the outlet end of the actuator 20 and being capable of controlling the movement of the outlet tube 12 in its own axis; the guide mechanism may direct the outlet tube 12 and pull the limited assembly 14 and cause it to move in the direction of the central axis of the extrusion outlet outer wall 11 to effect size adjustment of the outer wall 11 of the extrusion outlet.

Preferably, the first material guide openings are evenly spaced, and the first material guide holes are perpendicular to the lateral surface of the upper circular cut cone of the bounding block 14.

Specifically, the deflection mechanism comprises switching units 15 disposed at the wall of the outlet pipe 12; the switching units 15 are symmetrically disposed in relation to the axis of the discharge pipe 12, and the axis of the switching units 15 is distributed in the radial direction of the discharge pipe 12; the switching units 15 are connected to the output end of the actuator 20; the movement of the outlet tube 12 along its axis changes the state of the lower circular cut cone of the limited block 14 and the outer wall 11 of the extrusion outlet from the interconnection to the separation, from the separation to the interconnection.

Preferably, the actuator 20 comprises a motor 21 and a guide block 22; the guide block 22 is provided with the first pulling groove and the second pulling groove respectively, and the center line in the direction of the depth of the first pulling groove and the second pulling groove is respectively perpendicular to the surface of the guide block 22; the center line in the direction of the length of the first pulling groove is perpendicular to the axis of the outlet tube 12, and the center line in the direction of the length of the first pulling groove is in the same line as or parallel to the center line in the direction of the length of the second pulling groove; the outlet tube 12 passes through the first pulling groove, and the guide block 22 can move in the direction of the length of the first pulling groove; both sides of the first pulling groove provided with a guide rail, and the center line in the direction of the guide rail depth is perpendicular to the axis of the outlet tube 12; the guide rail is inclined and aligned with the switching unit 15; when the guide unit 22 moves in the direction of the length of the first pulling groove, the guide rail can push the switching unit 15 and pull the outlet tube 12 to control movement in its axial direction; the output axis of the motor 21 is coupled to the guide block 22 and the motor can supply rotational power to control the tilt of the guide block 22 and the direction of tilt of the guide block 22 is perpendicular to the center line in the direction of the guide rail depth.

Preferably, the sheath of the heating mechanism 30 is connected to the drain pipe 12 so as to heat the consumables inside the drain pipe 12; a heating mechanism 30 comprising a housing having an internal cavity housing a drain tube 12 and a guide block 22; the inner housing cavity is with the heat source in the direction of the axis of the outlet pipe 22.

Preferably, the holding mechanism 40 comprises a holding cavity housing the consumables; the outer wall of the storage cavity is coaxially provided with a plurality of evenly spaced annular ribs extending from the center; this arrangement allows the heat of the consumables to be dissipated inside the storage cavity so that the consumables inside the storage cavity are not damaged and softened by the excessive temperature caused by the thermal conductivity of the guide tube 12.

In the first operating state, the switching unit 15 is located at one end of the guide rail near the second pulling groove; in this case, the space between the circular cut cone of the limited block 14 and the outer wall 11 of the extrusion outlet is provided with a space for passage of consumables, and the outlet radius of the extrusion outlet is the radius of the extrusion outlet; the heating mechanism 30 heats the materials conveyed by the outlet tube 12, and the heated materials are discharged through the lower outlet opening of the outlet tube 12 formed through the annular sealing unit 13, the outer wall 11 of the extrusion outlet 14 and the upper circular cut cone; the supplies inside the cavity pass through the gap between the outer wall 11 of the extrusion outlet and the lower circular cut-off cone of the limited block 14 as well as the material guide of the limited block 14 and are fed to the extrusion outlet and extruded to the printing surface.

In the second operating state, when printing accuracy is to be increased, as well as decreasing the supply extrusion radius, the motor 21 will operate and its output shaft will control the movement of the guide block 22 towards the motor 21 along the centerline in the direction of the first pulling groove; a second pulling groove allows the output shaft to extend toward one end of the first pulling groove along the axis of the second pulling groove; moving in the direction of the length of the first pulling groove, the guide unit 22 will shift relative to the outlet tube 12; a guide rail disposed at the guide block 22 is applied by a force acting on the displacement unit 15 perpendicular to the length of the guide rail, and the applied force is directed from the switching unit 15 to the outer wall 11 of the extrusion outlet; the switching unit 15 moves towards the outer wall 11 of the extrusion outlet along the axis of the outlet tube 12 under the action of a guide rail; during movement, the outlet tube 12 connected to the switching unit 15 is forced to move towards the extrusion outlet along its axis, and the restricted unit 14 is forced to move towards the extrusion outlet; when the bounded block 14 reaches the extrusion outlet, the lower circular, bounded lower bound cone of the bounding block 14 coincides with the outer surface seal of the outer wall 11 of the extrusion outlet, and the lower surface of the lower circular cut cone and the extrusion outlet are in the same plane; at present, the radius of the extrusion outlet is the radius of the second material deflection of the lower block 14 of the round cut-off cone; due to the reduction of the extrusion outlet radius, the consumables are extruded at the same pressure, and the consumables are transported through the outlet tube 12 from the holding mechanism 40 to a cavity formed by an annular sealing unit 13, extrusion outlet outer wall 11, and cut cone; once introduced into the cavity, the consumables will be extruded through the guide block opening of the limited block 14 material to the printing surface, and then cooling and forming in the printing surface will occur.

Preferably, the outer wall 11 of the extrusion outlet is connected to the housing of the heating mechanism 30 via a threaded connection member 16 and the threaded connection member 16 is coaxially connected to the outlet pipe 12; the heating mechanism 30 having a mounting hole located on the same axis as the outlet pipe 12; the threaded connecting member 16 has an upper threaded connecting member connecting to the mounting opening of the housing 30 of the heating mechanism, as well as a lower threaded connecting member connecting to an outer wall 11 of the extrusion outlet, which is remote from the extrusion outlet; an upper threaded coupling member connected to the outer portion of the outlet tube 12 may stabilize the outlet tube 12 and prevent it from jumping in the radial direction; the threaded connecting member 16 is arranged to attach an outer wall 11 of the extrusion outlet, as well as a heating mechanism 30 such that the clearance of the outlet tube 12 is zero in its peripheral direction; when the guide rail causes the switching unit 15 to move towards the bottom of the guide block, the freedom of the outlet tube 12 is circularly limited through the threaded connecting member 16 such that the outlet tube 12 shifts to its circumferential direction when forced by the switching unit 15 the cut cone can fit on the conical surface of the outer wall of the extrusion outlet, ensuring stable operation of the unit.

Printing method for a dual-caliber 3D variable-speed printer, including:

51, powering the heating mechanism 30 when the confined block 14 and the inner wall of the extrusion outlet 11 are sealed together and the heat source will heat the consumables inside the discharge tube 12 until they are melted and the molten consumables are discharged from the discharge end of the storage mechanism 40; flowing into the bottom of the outlet tube 12 along the axis of the outlet tube 12, then being discharged through the outlet end of the lower end of the outlet tube 12, the cavity formed through the outer wall 11 of the extrusion outlet, the annular sealing unit 13;

52, first gradually increasing and then gradually decreasing the radius of the circular cut cone from the top of the limited block to the bottom, and forming a constituent of the round cut cone of the lower portion of the limited block parallel to the outer wall of the extrusion outlet. the lower end of the tube and is in the form of two coaxial round cut cones; a plurality of material deflection apertures located in the limited block, and the material deflection apertures including the first material deflection apertures and the second material deflection apertures; the first material deflection apertures are disposed in the upper circular cut-off cone of the limited block and are connected to the outlet apertures at the lower end of the dispensing tube through a ring formed by an annular sealing unit and an outer wall of the extrusion outlet; the second material deflection apertures are coaxially located at the bottom of the lower block's lower circular cut cone and are connected to the first material deflection apertures; the molten consumables contained in the cavity formed through the outer wall 11 of the extrusion outlet, the annular sealing unit 13 and the limited unit 14, are extruded internally from the extrusion outlet 11 through the second material guide apertures;

S3, when lowering the print accuracy requirement or increasing the extrusion radius, the motor 21 will operate and the output shaft of the motor 21 will control a guide unit 22 coupled to the output shaft in the central axis perpendicular to the outlet tube 12; a guide block 22 provided with a guide rail aligned with a switching unit 15 mounted on the wall of the drain tube 12; the displacement of the guide block 22 pushes the switching unit 15 and pulls the discharge tube 12, causing it to move upwardly along the central axis; the movement of the outlet tube 12 forces the restricted unit 14 to move in a direction away from the extrusion outlet outer wall 11 along the axis of the outlet tube 12, forming a gap between the restricted unit 14 and the extrusion outlet outer wall 11; the extrusion radius being the radius of the outer wall 11 of the extrusion outlet; the molten consumables contained in the cavity formed through the extrusion outlet outer wall 11, annular sealing unit 13 and the restricted unit 14, respectively pass through the gap between the extrusion outlet outer wall 11 and the limited unit 14, as well as the second material guide of the limited unit 14; and then fed into an extrusion outlet and extruded into a printable work surface through an extrusion outlet.

Preferably, in step S1, the annular ribs of the outer walls of the storage cavity exert heat to the materials inside the storage cavity so that the materials inside the cavity are not damaged and softened by the excessive temperature caused by the thermal conductivity of the guide tube 12.

Preferably, in step S3, when the guide rail causes the switching unit 15 to move towards the bottom of the guide block 22 and the discharge tube 12 towards the outer wall 11 of the extrusion outlet, the outer wall of the extrusion outlet is connected to the heating mechanism body via a threaded connector. the element is coaxially connected to a discharge pipe; the threaded coupling member comprises an upper threaded coupling member connecting to the heating mechanism housing mounting aperture, as well as a lower threaded connecting member connecting to an outer wall of the extrusion outlet remote from the extrusion outlet; the threaded coupling member 16 can stabilize the outlet tube 12 and prevent it from jumping in the radial direction; the freedom of the outlet tube 12 is limited in a circumferential direction through the threaded connecting member 16 such that the outlet tube 12 shifts in its circumferential direction controlled by a limited block 15.

Disclosed embodiments will enable the skilled artisan to realize or use the present invention, and various modifications of the embodiments will be apparent to those skilled in the art, and the principle defined herein may be embodied in other embodiments without departing from the scope or spirit of the present invention. Therefore, the present invention is not limited to the embodiments described, but encompasses a broad field of application, consistent with the principle and novel features of the invention.

Claims (1)

Definition of the Invention A dual size 3D printer sprayer comprising an extrusion outlet outer wall and a discharge tube; characterized in that the outer wall of the extrusion outlet is conical and has an inner cavity located on the same axis as the outer wall of the extrusion outlet; the discharge tube may inject molten consumables into the inner cavity of the outer wall of the extrusion outlet; the lower sidewall of the outlet tube being circumferentially arranged with a plurality of evenly spaced outlets; the annular sealing unit is positioned above the outlets and in the same axis as the outlet tube; an annular sealing unit mounted in the upper portion of the inner cavity of the outer wall of the extrusion outlet to separate and move along the axis of the outer wall of the extrusion outlet; the lower end of the outlet tube being connected to a control mechanism located in the cavity consisting of an annular sealing unit and an outer wall of the extrusion outlet; a control mechanism comprising a limited block coaxially connected to the lower end of the outlet tube in the form of two coaxial round cut cones; the radius of the bounded block of the upper circular cut cone to the lower round cut cone initially increases gradually and then gradually decreases; the constituent part of the circular cut cone on the lower part of the block being parallel to the constituent part of the outer wall of the extrusion outlet; the limited block has a plurality of material deflection openings including a plurality of deflection openings of the first material and deflection openings of the second material; the first material deflection apertures are disposed in a circular cut cone on the upper portion of the restricted block and are connected to the outlet apertures at the lower end of the outlet tube through a cavity formed by an annular sealing unit and an outer wall of the extrusion outlet; the second material deflection apertures are coaxially located at the bottom of the lower block's lower circular cut cone and are connected to the first material deflection apertures; the bottom of the outer wall of the extrusion outlet being provided with an extrusion outlet connected to the inner cavity of the outer wall of the extrusion outlet; the extrusion outlet is disposed on the same axis as the second material deflection apertures having a radius coinciding with the radius of the lower block of the lower circular cut cone; the diameter of the second material deflection holes being smaller than the extrusion outlet diameter, the middle portion of the outlet tube being guided, the guide end of the guide means being connected to the output end of the actuator and being able to control the movement of the outlet tube in its axial direction; the control mechanism can direct the outlet tube and pull the limited block and control its movement in the direction of the axis of the outer wall of the central extrusion outlet for effecting size adjustment of the outer wall opening of the extrusion outlet, the guide mechanism comprising switching units located on the outlet tube wall; the switching units are arranged symmetrically in relation to the axis of the discharge pipe, and the axis of the switching units is distributed in the radial direction of the discharge pipe; the shifting units are connected to the output end of the actuator, which can push the shifting units, pull the drain tube so that it moves along its axis, and change the status of the lower block's lower circular cut cone and outer wall of the extrusion outlet from the interconnection to the separation to the interconnection.