CN110665432A

CN110665432A - Pellet molding machine for conical feed mold

Info

Publication number: CN110665432A
Application number: CN201911098491.7A
Authority: CN
Inventors: 不公告发明人
Original assignee: Shishi City Gu Yun Clothing Design Co Ltd
Current assignee: Shishi City Gu Yun Clothing Design Co Ltd
Priority date: 2019-11-12
Filing date: 2019-11-12
Publication date: 2020-01-10

Abstract

The invention relates to the field of feed processing, in particular to a conical feed molding granulator which is characterized in that: the granulating device is fixedly arranged on the upper edge of the lower shell and is connected with the motor through a secondary speed reducer, the granulating device comprises an upper shell for containing materials, a conical die coaxially and fixedly arranged on the bottom edge of the upper shell in a large cone opening direction, an extruding assembly coaxially arranged in the upper shell and used for extruding the materials out of the conical die to form particles, and an adjusting mechanism coaxially arranged in the upper shell and used for adjusting a gap between the extruding assembly and the conical die, an extruding hole perpendicular to the conical surface is formed in the conical surface of the conical die, and the extruding assembly comprises a press roller of a conical structure and a transmission mechanism used for fixedly mounting the press roller and driving the press roller to revolve around the axis of the upper shell. The invention has simple structure, uniform and reasonable stress, convenient adjustment of the abrasion gap between the compression roller and the conical die and high working efficiency.

Description

Pellet molding machine for conical feed mold

Technical Field

The invention relates to the field of feed processing, in particular to a conical die granulator for feed.

Background

A feed granulator is a feed processing machine which directly presses particles by crushed materials of corns, bean pulp, straws, grasses, rice husks and the like, and is widely suitable for large, medium and small-sized aquaculture, grain feed processing plants, livestock farms, poultry farms, individual farmers, medium and small-sized farms, and farmers or large, medium and small-sized feed processing plants. The significance of pelletization lies in the ability to improve feed return, avoid animal picky food and make the transportation more economical and convenient.

At present, the types of the feed granulators on the market are many, and most of the feed granulators mainly adopt a flat die granulator or a ring die granulator. Some can meet the problem of the work efficiency of some very big reduction granulator such as the inhomogeneous granule of granulation is loose in-service use, the granulator in-service still has the serious condition of compression roller wearing and tearing simultaneously, and the compression roller wearing and tearing are inhomogeneous, and the maintenance is loaded down with trivial details still greatly reduced the efficiency of original work, shortens equipment life, thereby in addition because compression roller or flat-die wearing and tearing lead to the clearance between the two too big influence the pelletization output.

Disclosure of Invention

The invention aims to provide a conical feed mould granulator which is simple in structure, uniform and reasonable in stress, convenient to adjust the abrasion gap between a compression roller and a conical mould and high in working efficiency.

In order to solve the technical problems, the technical scheme adopted by the invention is as follows: a granulator for conical feed moulds comprises a frame, a lower shell fixedly connected to the frame, a motor and a granulating device, wherein the granulating device is fixedly arranged at the upper edge of the lower shell and is connected with the motor through a two-stage speed reducer, the granulating device comprises an upper shell for containing materials, a conical die coaxially and fixedly arranged at the bottom edge of the upper shell in the direction of a large cone opening, an extruding assembly coaxially arranged in the upper shell and used for extruding the materials out of the conical die to form granules, and an adjusting mechanism coaxially arranged in the upper shell and used for adjusting a gap between the extruding assembly and the conical die, an extruding hole vertical to a conical surface is arranged on the conical surface of the conical die, the extruding assembly comprises at least one compression roller with a conical structure and a transmission mechanism used for fixedly mounting the compression roller and driving the compression roller to revolve around the axis of the upper shell, the conical surface of the compression roller is tangent to the inner surface of the conical die, and the axis of the compression roller is coplanar with, the upper end surface of the upper shell is provided with a feed inlet, the material is effectively extruded by the rotation effect generated by the revolution of the compression roller with a conical structure during extrusion, in addition, the centrifugal force effect is generated on the material under the action of the rotary motion of the transmission mechanism, so that the material can be dispersed around, because the conical die is of the conical structure, the material is extruded by the compression roller and is also extruded out of the conical die easily under the action of the centrifugal force, the production efficiency is effectively improved, and the caking phenomenon can not be generated, in addition, the adjustment of the gap between the compression roller and the conical die by the adjusting mechanism avoids the phenomenon that the extrusion efficiency is influenced by the overlarge material thick layer caused by the overlarge gap and the excessive abrasion between the compression roller and the conical die caused by the undersize gap, in addition, the gap between the compression roller and the conical die can be conveniently adjusted when the gap between the compression roller and the conical die, the maximization of the pelletizing productivity and the minimization of the abrasion are realized.

Furthermore, the compression roller is rotatably arranged on the transmission mechanism through a roller shaft, the roller shaft is connected with the transmission mechanism through a bearing D, and through the structure, the compression roller can perform revolution motion around the axis of the upper shell, and simultaneously generates rotation motion under the resistance action of materials in the extrusion process, so that the production efficiency and the product quality are effectively improved.

Further, the transmission mechanism comprises an upper frame body, a lower cone body, a transmission shaft and a shaft sleeve, the upper frame body comprises a bottom plate and two wing plates, one ends of the two wing plates are fixedly connected with the bottom plate, the other ends of the two wing plates are free ends, the two wing plates are obliquely arranged on the edge of the bottom plate in a mode that the distance between the two wing plates is gradually increased from a connecting end to the free ends, the shaft sleeve is fixedly connected with the bottom plate, the shaft sleeve and the wing plates are positioned at the same side of the bottom plate, the transmission shaft penetrates through the bottom plate and is embedded in the shaft sleeve and is fixedly connected with the shaft sleeve, the lower cone body is coaxially and fixedly connected with the lower end part of the shaft sleeve, the lower cone body and the wing plates are correspondingly arranged to form two groups of compression roller mounting frames, the wing plates and the conical surface of the lower cone body are arranged in parallel, the vertical distance between the wing plates and the lower cone, the transmission mechanism is arranged in the upper shell in a mode that the free end of the wing plate faces the bottom of the upper shell, and the transmission shaft is coincided with the axis of the upper shell, the bottom of the lower cone is coaxially and fixedly connected with a hollow sleeve which is consistent with the bottom surface of the lower cone in shape, and the upper frame body is of a symmetrical structure, so that two compression rollers are adopted and are arranged on the transmission mechanism to form a symmetrical structure, the production efficiency can be ensured, three or more groups of compression rollers and wing plates which are uniformly arranged along the circumferential direction of the upper shell can be arranged according to the number of the wing plates on the compression rollers and the upper frame body under the condition that the space of the granulator is allowed, and two.

Further, pterygoid lamina and lower cone all are provided with the roller mounting hole, are located the coaxial setting of roller mounting hole on same a set of pterygoid lamina and the lower cone, adopt this kind of structure, are convenient for carry out fixed mounting to the compression roller.

Further, the adjusting mechanism comprises a fixed bottom plate, a spring, an adjusting shaft sleeve and adjusting nuts, the outer diameter of the fixed bottom plate is consistent with the inner diameter of the hollow sleeve and is arranged in the hollow sleeve, the fixed bottom plate is connected with the lower cone through the spring, the spring is sleeved on the transmission shaft and enables the spring to coincide with the axis of the transmission shaft, the adjusting shaft sleeve is arranged at the upper end of the transmission mechanism and is in contact with the upper end face of the bottom plate and sleeved on the transmission shaft and is coaxially and fixedly connected with the transmission shaft, the adjusting nuts are arranged at the upper end of the adjusting shaft sleeve and are in coaxial threaded connection with the transmission shaft for pressing the adjusting shaft sleeve so as to press the transmission mechanism, the number of the adjusting nuts is 2, a section of thread is turned at the upper part of the transmission shaft for threaded connection of the transmission shaft and the adjusting nuts, when the gap between the compression roller and, the transmission mechanism axially moves on the transmission shaft, the gap between the compression roller and the conical die is ensured to be within an acceptable range, the maximization of granulation productivity and the minimization of abrasion are realized, and the adjusting mechanism is convenient to adjust, stable in structure and firm.

Furthermore, the coaxial fixedly connected with in adjustment axle sleeve upper end edge divides the flitch with the umbelliform that umbrella mouth direction set up downwards, divides the flitch to set up under the feed inlet, when powder flitch and transmission shaft co-rotation, can be better with the material dispersion to the extrusion pelletization region that gets into for material bed of material thickness is even relatively, guarantees that the compression roller is unanimous to the extrusion force of material, also is even relatively to the wearing and tearing of compression roller and conical die simultaneously, has effectively improved the life of equipment.

Further, the one end of awl mould and last casing bottom edge fixed connection still with the top edge fixed connection of lower casing, it is located the both sides of awl mould respectively to go up casing and lower casing, it has the discharge gate to open the casing lower extreme down, the other end fixedly connected with mount pad of awl mould, the transmission shaft passes through the rotatable connection of bearing C in the mount pad, the mount pad is cylinder tube-shape and internal diameter and the external diameter of hollow sleeve unanimous and makes on the mount pad is placed in to the hollow sleeve is coaxial, the one end edge of awl mould passes through bolt assembly and last casing and lower casing fixed connection, the other end of awl mould passes through screw fixed connection with the mount pad that is connected to the transmission epaxial, the rotatable setting of transmission shaft is in the mount pad, make the integral support of awl mould more reasonable, guarantee that pelletization extrusion process is. The discharge gate below is connected with the groove that gathers materials, conveniently collects the material granule, and in addition, the upper portion position of hollow sleeve's surface still installs dustproof sealing circle, prevents that the powder from getting into in the mount pad.

Furthermore, the lower end of the conical die is provided with a blade matched with the shape of the conical die, the blade is fixedly connected to a discharging assembly, and the discharging assembly comprises a scraper seat coaxially and fixedly connected to the transmission shaft and a discharging scraper fixedly connected to the scraper seat and rotating along with the transmission shaft. The blade is used for swift, accurate cutting off from the column material that extrudes in the extrusion hole on the conical die, through the key-type connection between scraper seat and the transmission shaft, through the rotation of ejection of compact scraper blade, promotes the material granule and falls into the groove that gathers materials from the discharge gate, and then conveniently collects. The whole structure is simple, and the installation and the disassembly are convenient.

Further, the one end of transmission shaft is passed through bearing A rotatable setting on last casing and the other end passes through bearing B rotatable setting in the frame, the transmission shaft adopts both ends to support, make the transmission shaft atress more even reasonable when the pelletization, the life of extension equipment, go up the casing in addition and all install the end cover on the bearing position of transmission shaft, be used for preventing the powder entering, dustproof end cover is all installed at the upper and lower both ends of the bearing position of transmission shaft to the frame, be used for preventing the powder entering, the feeder hopper that is linked together with the feed inlet is still installed to the upper end of going up the casing, conveniently throw the material, the gyro wheel is still installed to frame bottom in addition, make things.

As can be seen from the above description, the feed cone molding granulator effectively extrudes the material through the autorotation effect generated during extrusion while the compression roller with the cone structure revolves, and in addition, the centrifugal force effect is generated on the material under the action of the rotary motion of the transmission mechanism, so that the material can be dispersed all around, because the cone mold is of the cone-shaped structure, the material is extruded by the compression roller and is also extruded out of the cone mold under the action of the centrifugal force, the production efficiency is effectively improved, the caking phenomenon is not generated, in addition, the adjustment of the gap between the compression roller and the cone mold through the adjusting mechanism avoids the extrusion efficiency caused by the overlarge thick layer of the material due to the overlarge gap and the excessive abrasion between the compression roller and the cone mold due to the undersize gap, in addition, the adjustment can be convenient when the gap between the compression roller and the cone mold is increased due to the abrasion of the compression roller and, the clearance is ensured to be within an acceptable range, the maximization of granulation productivity and the minimization of abrasion are realized, the structure is simple, the stress is uniform and reasonable, the operation is convenient, and the working efficiency is high.

Drawings

Fig. 1 is a schematic structural view of a feed cone molding granulator according to the present invention.

Fig. 2 is a partial schematic view of a feed cone molding granulator according to the present invention.

In the figure: 1-a motor; 2-a frame; 3-a lower shell; 4-a granulating device; 5-a feed hopper; 6-an adjusting mechanism; 7-extruding assembly; 8-a transmission mechanism; 9-a discharge assembly; 10-a material collecting groove; 11-a secondary reduction unit; 12-a mounting seat; 13-a spring; 14-dustproof sealing ring; 15-a blade; 16-extrusion orifices; 17-a conical die; 18-a bolt assembly; 19-bearing D; 20-mounting the frame body; 21-an upper shell; 22-a material distributing plate; 23-adjusting the nut; 24-bearing a; 25-end cap; 26-a feed inlet; 27-adjusting the shaft sleeve; 28-a base plate; 29-wing plate; 30-shaft sleeve; 31-a press roll; 32-roll axis; 33-lower conical plate; 34-a hollow sleeve; 35-a discharge scraper; 36-a squeegee mount; 37-dust-proof end covers; 38-bearing C; 39-fixing the bottom plate; 40-bearing B; 41-a discharge hole; 42-a roller; 43-a drive shaft; 44-roller mounting holes; 45-roll mount.

Detailed Description

The invention is further described below by means of specific embodiments.

As shown in fig. 1 and 2, the pellet mill for molding a feed cone of the present invention comprises a frame 2, a lower housing 3 fixedly connected to the frame 2, a motor 1 and a pellet mill 4, wherein the pellet mill 4 is fixedly installed at an upper edge of the lower housing 3 and is connected to the motor 1 through a two-stage speed reducer 11, and is characterized in that: the granulating device 4 comprises an upper shell 21 for containing materials, a conical die 17 which is coaxially and fixedly arranged at the bottom edge of the upper shell 21 in a large cone mouth direction, a material extruding assembly 7 which is coaxially arranged in the upper shell 21 and enables the materials to be extruded out of the conical die 17 to form granules, and an adjusting mechanism 6 which is coaxially arranged in the upper shell 21 and is used for adjusting a gap between the material extruding assembly 7 and the conical die 17, wherein an extruding hole 16 which is vertical to a conical surface is arranged on the conical surface of the conical die 17, the material extruding assembly 7 comprises at least one press roller 31 which is used for extruding the materials and is in a conical structure, and a transmission mechanism 8 which is used for fixedly arranging the press roller 31 and driving the press roller 31 to revolve around the axis of the upper shell 21, the conical surface of the press roller 31 is tangent to the inner surface of the conical die 17, and the axis of the press roller 31 is coplanar with the axis of the upper shell 21, the upper end surface of the upper shell 21 is provided with a feed inlet 26. The pressure roller 31 is rotatably disposed on the transmission mechanism 8 via a roller shaft 32. The transmission mechanism 8 comprises an upper frame body 20, a lower cone 33, a transmission shaft 43 and a shaft sleeve 30, wherein the upper frame body 20 comprises a bottom plate 28 and two wing plates 29, one end of each wing plate 29 is fixedly connected with the bottom plate 28, the other end of each wing plate 29 is a free end, the two wing plates 29 are obliquely arranged on the edge of the bottom plate 28 in a manner that the distance between the two wing plates is gradually increased from a connecting end to the free end, the shaft sleeve 30 is fixedly connected with the bottom plate 28, the shaft sleeve 30 is positioned on the same side of the bottom plate 28 as the wing plates 29, the transmission shaft 43 penetrates through the bottom plate 28 and is embedded in the shaft sleeve 30 and is fixedly connected with the shaft sleeve 30, the lower cone 33 is coaxially and fixedly connected with the end part of the lower end of the shaft sleeve 30, the lower cone 33 and the wing plates 29 are correspondingly arranged to form two sets of mounting frame pressing rollers, and the conical surfaces of the wing plates 29 and the lower cone 33 The distance is greater than the height of compression roller 31, compression roller 31 is two and passes through roller 32 is rotatable set up in compression roller mounting bracket 45, compression roller 31 set up in pterygoid lamina 29 with down between the cone 33 and with pterygoid lamina 29 with all have the clearance down between the cone 33, drive mechanism 8 with the free end orientation of pterygoid lamina 29 the mode of the bottom of last casing 21 set up in last casing 21 and make the transmission shaft 43 with the axis coincidence of last casing 21, the coaxial fixedly connected with in cone 33 bottom down with the hollow sleeve 34 that cone 33 bottom surface shape is unanimous down. The wing plates 29 and the lower cone 33 are provided with roller shaft mounting holes, and the roller shaft mounting holes 44 on the wing plates 29 and the lower cone 33 in the same group are coaxially arranged. The adjusting mechanism 6 comprises a fixed bottom plate 39, a spring 13, an adjusting shaft sleeve 27 and adjusting nuts 23, the outer diameter of the fixed bottom plate 39 is consistent with the inner diameter of the hollow sleeve 34 and is arranged in the hollow sleeve 34, the fixed bottom plate 39 is connected with the lower cone 33 through the spring 13, the spring 13 is sleeved on the transmission shaft 43 and enables the spring 13 to coincide with the axis of the transmission shaft 43, the adjusting shaft sleeve 27 is arranged at the upper end of the transmission mechanism 8 and is in contact with the upper end face of the bottom plate 28 and sleeved on the transmission shaft 43 and is coaxially and fixedly connected with the transmission shaft 43, the adjusting nuts 23 are arranged at the upper end of the adjusting shaft sleeve 27 and are coaxially and threadedly connected with the transmission shaft 43 and are used for pressing the adjusting shaft sleeve 27 so as to press the transmission mechanism 8, and the number of the adjusting nuts 23 is 2. The upper end edge of the adjusting shaft sleeve 27 is coaxially and fixedly connected with an umbrella-shaped material distributing plate 22 which is downwards arranged in the umbrella opening direction. The conical die 17 and one end of the bottom edge of the upper shell 21 are fixedly connected with the top edge of the lower shell 3, the upper shell 21 and the lower shell 3 are respectively positioned at two sides of the conical die 17, a discharge hole is formed in the lower end of the lower shell 3, the other end of the conical die 17 is fixedly connected with the mounting seat 12, the transmission shaft 43 is rotatably connected into the mounting seat 12 through a bearing C38, and the mounting seat 12 is cylindrical and has the same inner diameter as the outer diameter of the hollow sleeve 34 and enables the hollow sleeve 34 to be coaxially arranged in the mounting seat 12. The lower end of the conical die 17 is provided with a blade 15 matched with the conical die 17 in shape, the blade 15 is fixedly connected to a discharging assembly 9, and the discharging assembly 9 comprises a scraper seat 36 coaxially and fixedly connected to the transmission shaft 43 and a discharging scraper 35 fixedly connected to the scraper seat 36 and rotating along with the transmission shaft 43. One end of the transmission shaft 43 is rotatably disposed on the upper housing 21 through a bearing a24, and the other end is rotatably disposed on the frame 2 through a bearing B40.

The use method of the feed cone molding granulator comprises the following steps: after the equipment is started, materials are put into the feed hopper 5, fall onto the material distribution plate 22 rotating along with the transmission shaft 43 through the feed inlet 26, are quickly and uniformly dispersed onto the conical die 17 under the action of the material distribution plate 22, are extruded out of the extrusion holes 16 on the conical die 17 under the extrusion action of the press roll 31 which is driven by the transmission mechanism 8 to do revolution motion, are quickly and accurately cut off columnar materials extruded out of the extrusion holes 16 on the conical die 17 through the cutting action of blades, form particles with consistent particle size, are pushed out from the discharge hole 41 of the lower shell 3 and fall into the material collection groove 10 under the action of the discharge scraper 35 rotating along with the transmission shaft 43, are convenient for subsequent collection and storage, and when the gap between the press roll 31 and the conical die 17 is increased due to abrasion after working for a period of time, the adjusting nut 23 on the adjustable adjusting mechanism 6 pushes the adjusting sleeve 27 and further pushes the transmission mechanism 8 to extrude and compress the spring 13, so that the transmission mechanism 8 axially moves on the transmission shaft 43, and the gap between the compression roller 31 and the conical die 17 is adjusted, thereby maximizing the pelletizing productivity and minimizing the abrasion.

The above description is only a few specific embodiments of the present invention, but the design concept of the present invention is not limited thereto, and any insubstantial modifications made by the design concept should fall within the scope of the present invention.

Claims

1. A fodder cone molding granulator comprises a frame, a lower shell fixedly connected to the frame, a motor and a granulating device, wherein the granulating device is fixedly installed on the upper edge of the lower shell and connected with the motor through a secondary speed reduction device, and is characterized in that: the granulating device comprises an upper shell for containing materials, a conical die which is coaxially and fixedly arranged on the edge of the bottom of the upper shell in the direction of a large cone opening and is in a conical shape, an extruding assembly which is coaxially arranged in the upper shell and enables the materials to be extruded out of the conical die to form particles, and an adjusting mechanism which is coaxially arranged in the upper shell and is used for adjusting the gap between the extruding assembly and the conical die, the conical surface of the conical die is provided with an extrusion hole vertical to the conical surface, the extrusion assembly comprises at least one compression roller with a conical structure for extruding materials and a transmission mechanism for fixedly mounting the compression roller and driving the compression roller to revolve around the axis of the upper shell, the conical surface of the compression roller is tangent to the inner surface of the conical die, the axis of the compression roller is coplanar with the axis of the upper shell, and the upper end surface of the upper shell is provided with a feed inlet.

2. The feed cone molding pellet machine of claim 1, wherein: the compression roller is rotatably arranged on the transmission mechanism through a roller shaft.

3. The feed cone molding pellet machine of claim 2, wherein: the transmission mechanism comprises an upper frame body, a lower cone, a transmission shaft and a shaft sleeve, the upper frame body comprises a bottom plate and two wing plates, one ends of the two wing plates are fixedly connected with the bottom plate, the other ends of the two wing plates are free ends, the two wing plates are obliquely arranged on the edge of the bottom plate in a mode that the distance between the two wing plates is gradually increased from a connecting end to the free ends, the shaft sleeve is fixedly connected with the bottom plate, the shaft sleeve and the wing plates are positioned on the same side of the bottom plate, the transmission shaft penetrates through the bottom plate and is embedded in the shaft sleeve and fixedly connected with the shaft sleeve, the lower cone is coaxially and fixedly connected with the lower end part of the shaft sleeve, the lower cone and the wing plates are correspondingly arranged to form two groups of compression roller mounting frames, the wing plates and the conical surface of the lower cone are arranged in parallel, and the vertical distance between, the compression roller is two and passes through the roller is rotatable set up in the compression roller mounting bracket, the compression roller set up in the pterygoid lamina with down between the cone and with the pterygoid lamina with all have the clearance down between the cone, drive mechanism with the free end orientation of pterygoid lamina the mode of the bottom of going up the casing set up in the upper casing and make the transmission shaft with the axis coincidence of upper casing, down the coaxial fixedly connected with in cone bottom with the hollow sleeve that cone bottom surface shape is unanimous down.

4. The feed cone molding pellet machine of claim 3, wherein: the pterygoid lamina with the cone all is provided with the roller mounting hole down, is located same one set of the pterygoid lamina with on the cone down the coaxial setting of roller mounting hole.

5. The feed cone molding pellet machine of claim 3, wherein: the adjusting mechanism comprises a fixed bottom plate, a spring, an adjusting shaft sleeve and adjusting nuts, wherein the outer diameter of the fixed bottom plate is consistent with the inner diameter of the hollow sleeve and is arranged in the hollow sleeve, the fixed bottom plate is connected with the lower cone through the spring, the spring is sleeved on the transmission shaft and enables the spring to be superposed with the axis of the transmission shaft, the adjusting shaft sleeve is arranged at the upper end of the transmission mechanism and is in contact with the upper end face of the bottom plate, the adjusting shaft sleeve is sleeved on the transmission shaft and is coaxially and fixedly connected with the transmission shaft, the adjusting nuts are arranged at the upper end of the adjusting shaft sleeve and are coaxially and threadedly connected with the transmission shaft and are used for pressing the adjusting shaft sleeve to tightly press the transmission mechanism, and the number of the adjusting nuts is.

6. The feed cone molding pellet machine of claim 5, wherein: the edge of the upper end of the adjusting shaft sleeve is coaxially and fixedly connected with an umbrella-shaped material distributing plate which is arranged downwards in the direction of an umbrella opening.

7. The feed cone molding pellet machine of claim 3, wherein: the conical die with go up casing bottom edge fixed connection's one end still with the top edge fixed connection of casing down, go up the casing with the casing is located respectively down the both sides of conical die, lower casing lower extreme is opened there is the discharge gate, the other end fixedly connected with mount pad of conical die, the transmission shaft pass through bearing C rotatable connect in the mount pad, the mount pad be cylinder tube-shape and internal diameter with hollow sleeve's external diameter is unanimous and makes hollow sleeve places in coaxial on the mount pad.

8. The feed cone molding pellet machine of claim 3, wherein: the lower end of the conical die is provided with a blade matched with the conical die in shape, the blade is fixedly connected to a discharging assembly, and the discharging assembly comprises a scraper seat coaxially and fixedly connected to the transmission shaft and a discharging scraper fixedly connected to the scraper seat and rotating along with the transmission shaft.

9. The feed cone molding pellet machine of claim 3, wherein: one end of the transmission shaft is rotatably arranged on the upper shell through a bearing A, and the other end of the transmission shaft is rotatably arranged on the rack through a bearing B.