JP2004188357A - Basket type extrusion granulator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a basket type extrusion granulator which can be easily and surely assembled, disassembled and cleaned, in which cleaned and dried state can be easily checked and in which the amount of a remaining kneaded matter remaining in a granulation chamber after operation is reduced. <P>SOLUTION: The kneaded matter is fed from a circular cylindrical hopper 1 via a pressurizing blade 2, the kneaded matter is guided to a circular cylindrical screen 4 via an extruding blade 3 for granulation. Granulates are received on a rotary table 5. Drive shafts 6, 7 and 37 of the extruding blade 3, the pressurizing blade 2 and the rotary table 5 are air-shaft-sealed with air-shaft-sealing boxes 20, 15 and 38, respectively. The pressurizing blade 2 and the extruding blade 3 are formed as integrated parts of boss sections 2a and 3a and blade sections 2b and 3b. For securing the blade 2 and the blade 3, square holes 2c and 3c formed in the bosses are fitted on square shaft sections 7b and 6c formed on the drive shafts on which the blade sections are provided. The hopper 1, the screen 4, the blade 2, the blade 3 and the table 5 are detachably secured. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a wet extruding granulator of a granular material, and more particularly to an extruding granulator called a basket type or a cylindrical type.
[0002]
[Prior art]
Conventionally, basket-type extrusion granulators are known, and are generally used, for example, in the fields of medicine and food. This basket type extrusion granulator produces a cylindrical granulated product by extruding a material obtained by kneading powder and liquid radially from a cylindrical screen with extrusion blades in a manufacturing process such as a granule. is there. In addition, the kneaded material used as the said material is supplied to an extrusion blade via a pressure blade from a hopper. The granulated product extruded radially from the screen falls on the rotary table, is scraped off by a scraper provided at one location of the rotary table, is discharged, and is supplied to the granulating device and drying device in the next process. The
[0003]
In such basket-type extrusion granulators, conventionally, each rotary drive shaft of the pressure blades and extrusion blades, and the rotary drive shaft of the rotary table, respectively, in order to prevent foreign matter from entering the drive side, respectively. Only an oil seal was applied.
[0004]
In addition, as disclosed in the following Patent Document 1 and Patent Document 2, the conventional pressure blade and extrusion blade have a cylindrical mounting boss portion and are integrated with the rotation shaft via a key or the like. It was attached to rotate.
[0005]
Further, as disclosed in each of these patent documents, conventional pressure blades and extrusion blades are configured by detachably attaching a plurality of components. That is, the pressure blade that supplies the kneaded material to the extrusion blade has a blade body made of a plate material at the tip of each of a plurality of arms (rotary blades) extending from the mounting boss portion to the rotating shaft, and a bolt nut or screw. It was attached detachably. Similarly, the extrusion blade that extrudes the kneaded material from the screen also has a blade body made of a plate material attached to each end of a plurality of arms (rotary blades) extending from the mounting boss portion on the rotation shaft with a bolt nut or screw. It was attached detachably.
[0006]
[Patent Document 1]
JP-A-8-89782
[Patent Document 2]
No. 6-12824
[0007]
[Problems to be solved by the invention]
However, the conventional structure has various problems as described below. In particular, there were many problems when viewed from GMP in pharmaceutical preparations and HACCP in food production.
[0008]
That is, the conventional pressure blades and extrusion blades have a blade body made of a plate material attached to a plurality of bolts and nuts at the tips of a plurality of arms (rotary blades) extending from the mounting boss portion to the rotation drive shaft. The blades are detachably attached with screws, and the bosses of the blades configured in this manner are attached to the rotary drive shaft through the keys. Therefore, the number of parts is extremely large, management thereof is complicated, disassembly and assembly are troublesome, and cleaning is inconvenient. In particular, cleaning the threaded portion was difficult and troublesome.
[0009]
In addition, each rotary drive shaft of the pressure blade, extrusion blade and rotary table is equipped with an oil seal, bearing, oil-impregnated bush bearing, etc., but it is difficult to remove the kneaded material adhering to these, and cross contamination due to poor removal occurs. There was a risk. In addition, kneaded materials, washing water, etc. infiltrated into these parts during washing, and harmful bacteria may be generated. Further, it is desirable that the shaft seal portion can be confirmed in the cleaning validation, but in the conventional structure, the presence of water, powder, etc. and the drying cannot be confirmed. Note that these points are particularly important in the field of pharmaceuticals, and if there is a residue, not only is it unsanitary, but there is a possibility that the medicinal effect and the like may change.
[0010]
Furthermore, as is apparent from the above-mentioned patent documents, the conventional pressure blade and extrusion blade have a cylindrical mounting boss portion and an elongated arm (rotary blade). Therefore, the space between the arms at the arm base end portion is large, and the kneaded material tends to stay in the space. Therefore, a large amount of residue remains in the apparatus when the operation is stopped, and the recovery rate is reduced. This has been a serious problem especially in the granulation of pharmaceuticals, which are very expensive in raw material costs.
[0011]
The present invention has been made in view of the above circumstances, and its main purpose is basket-type extrusion granulation that is easy to assemble and disassemble and clean, can be validated for cleaning, and has a small residual amount of raw materials when operation is stopped. Is to provide a machine. Particularly preferably, in response to GMP and HACCP, it is possible to prevent contamination of powder particles and cleaning liquid into shaft seals and bearing parts such as oil seals and bearings, and to keep these parts dry, and cross contamination. Another object of the present invention is to provide a basket type extrusion granulator that prevents generation of bacteria and bacteria, enables washing validation, and has a small residual amount of raw material kneaded material remaining in the apparatus when operation is stopped.
[0012]
[Means for Solving the Problems]
In order to achieve the above object, the present invention provides a basket-type extrusion granulator, in which a kneaded product is supplied from a hopper and guided to a cylindrical screen through the extrusion blade, and granulated. The rotary drive shaft is between the outer member through which the rotary drive shaft passes, and air is jetted upward between the inner peripheral surface of the upper end portion of the outer member and the outer peripheral surface of the rotary drive shaft. A seal can be formed.
[0013]
More specifically, the basket-type extrusion granulator of the present invention has the following structural requirements (A) to (F), and is provided between the inner peripheral surface of the upper end portion of the outer drive shaft and the outer peripheral surface of the inner drive shaft. Further, it is characterized in that a shaft seal air seal can be formed by jetting air upward.
(A) A cylindrical hopper into which the kneaded material is charged.
(B) A cylindrical screen provided at the bottom of the hopper and having a plurality of holes.
(C) A pressure blade provided inside the hopper and supplying the charged kneaded material downward.
(D) An extrusion blade that is provided inside the screen and rotates in the direction opposite to the pressure blade to extrude the kneaded material from the screen.
(E) A cylindrical outer drive shaft provided with an extrusion blade at the upper end.
(F) A rod-shaped inner drive shaft that is inserted into the outer drive shaft so as to be relatively rotatable, extends further upward from the outer drive shaft, and is provided with a pressure blade at the extension.
[0014]
In the case of this configuration, a shaft seal air seal can be formed between the inner drive shaft (pressure blade rotation shaft) and the outer drive shaft (extrusion blade rotation shaft) that rotate in opposite directions. Therefore, it is possible to prevent mixing of kneaded material into the shaft seal part and intrusion of cleaning water by ejecting air and forming a shaft seal air seal, especially during the disassembly and cleaning operation after the granulation operation. Become. In addition, operations such as sprinkling cleaning can be performed easily and efficiently. Further, the shaft seal portion can be kept in a dry state by seal air, and the generation of harmful bacteria can be prevented.
[0015]
Moreover, the basket type extrusion granulator of the present invention has the following structural requirements (A) to (G), and air is supplied upward between the inner peripheral surface of the upper end of the case lid and the outer peripheral surface of the outer drive shaft. A shaft seal air seal can be formed by jetting.
(A) A cylindrical hopper into which the kneaded material is charged.
(B) A cylindrical screen provided at the bottom of the hopper and having a plurality of holes.
(C) A pressure blade provided inside the hopper and supplying the charged kneaded material downward.
(D) An extrusion blade that is provided inside the screen and rotates in the direction opposite to the pressure blade to extrude the kneaded material from the screen.
(E) A cylindrical outer drive shaft provided with an extrusion blade at the upper end.
(F) A rod-shaped inner drive shaft that is inserted into the outer drive shaft so as to be relatively rotatable, extends further upward from the outer drive shaft, and is provided with a pressure blade at the extension.
(G) A case lid disposed under the extrusion blade and through which a drive double shaft including an outer drive shaft and an inner drive shaft passes.
[0016]
In the case of this configuration, a shaft seal air seal can be formed between the rotating outer drive shaft (pushing blade rotation shaft) and a member (case lid) disposed on the outer drive shaft. Therefore, it is possible to prevent mixing of kneaded material into the shaft seal part and intrusion of cleaning water by ejecting air and forming a shaft seal air seal, especially during the disassembly and cleaning operation after the granulation operation. Become. In addition, operations such as sprinkling cleaning can be performed easily and efficiently. Further, the shaft seal portion can be kept in a dry state by seal air, and the generation of harmful bacteria can be prevented.
[0017]
The basket-type extrusion granulator of the present invention preferably has, in addition to the above configuration, a disk-shaped rotary table that receives a granulated product that is radially extruded from the cylindrical screen, and is rotatable below the screen. Retained. The table drive shaft for rotationally driving the rotary table is located between the outer peripheral surface of the outer member and the outer peripheral surface of the table drive shaft between the outer member through which the table drive shaft passes. It is characterized in that a shaft seal air seal can be formed by ejecting air to the shaft.
[0018]
In the case of this configuration, a shaft seal air seal can be formed between the table drive shaft of the rotary table and a member arranged outside thereof. Therefore, it is possible to prevent mixing of kneaded material into the shaft seal part and intrusion of cleaning water by ejecting air and forming a shaft seal air seal, especially during the disassembly and cleaning operation after the granulation operation. Become. In addition, operations such as sprinkling cleaning can be performed easily and efficiently. Further, the shaft seal portion can be kept in a dry state by seal air, and the generation of harmful bacteria can be prevented.
[0019]
The shaft seal air seal is preferably performed through a shaft seal air box in which a through hole through which a shaft seal target rotating shaft is passed is formed. In this case, a seal air jet nozzle for shaft seal air seal is formed at the upper end of the shaft seal air box. Further, the through-hole of the shaft seal air box is a large-diameter hole at the lower portion thereof, which is supplied with seal air for shaft seal air seal and accumulates the seal air. In the lower part of the large-diameter hole, the shaft seal air box is attached while being kept airtight with the shaft seal target rotating shaft via a packing.
[0020]
In the case of this configuration, the shaft seal air seal of each part can be realized with a simpler structure and effectively. Further, if necessary, a bearing for rotating and holding the shaft-sealing target rotating shaft can be arranged in the shaft-sealing air box. In that case, what is necessary is just to arrange | position a bearing to the lower part of an oil seal (packing).
[0021]
In addition, in this configuration, mixing of the kneaded material into the shaft seal portion and intrusion of cleaning water in the disassembly work after granulation operation into the shaft seal air box equipped with an oil seal (or bearing) is prevented. This makes it possible to easily and efficiently perform operations such as water spray cleaning. At the same time, the shaft seal can be kept dry by the seal air to prevent the generation of harmful bacteria. Further, in the cleaning validation, the integrated shaft seal air box and oil seal (or bearing) can be removed and the inside thereof can be confirmed.
[0022]
Further, the basket type extrusion granulator of the present invention is supplied with a kneaded product from a hopper via a pressure blade, and guides the kneaded material to a cylindrical screen via the extrusion blade to perform granulation. In the granulator, either one or both of the pressure blade and the extrusion blade are integrally formed by a bearing boss portion at the center and a blade (an arm and a blade body at the tip portion) extending from the outer peripheral portion. It is formed as one part, and the boss portion is formed in a substantially truncated cone shape whose diameter is expanded downward.
[0023]
In the case of this configuration, the pressurizing blade and the extrusion blade are formed on the outer peripheral surface having a tapered shape with a longitudinal section of the boss portion attached to the rotation drive shaft having a substantially truncated cone shape and a diameter increasing toward the lower side. Yes. In the case of this configuration, not only the boss portion and the arm, but also the blade body at the tip of the arm are all integrally formed as one component. By eliminating the threaded portion for attaching the blade body or the like, cleaning can be performed easily and reliably.
[0024]
When the pressure blade has such a configuration, the kneaded material is smoothly guided to the cylindrical screen, and the structure is simplified to facilitate cleaning of the deposits, and to facilitate disassembly, cleaning and assembly. Can do. Further, when the extrusion blade has such a configuration, the kneaded material is smoothly guided to the cylindrical screen, the space volume inside the screen is reduced, the extrusion pressure to the cylindrical screen is increased, and the extrusion capability is increased. Increase, reduce the residual kneaded material in the granulation chamber after granulation operation, improve the recovery rate, simplify the structure, make it easy to clean the deposits, facilitate disassembly, cleaning and assembly .
[0025]
Further, in addition to the above configuration, either one or both of the pressure blade and the extrusion blade have a square hole formed in the boss portion, and a square shaft portion formed in the drive shaft provided with the blade, A basket-type extrusion granulator characterized by being detachably fitted and attached.
[0026]
In this configuration, since the blade can be mounted on the rotary drive shaft without using a key, not only the number of parts can be reduced, but also disassembly, cleaning, and assembly are facilitated.
[0027]
The basket-type extrusion granulator of the present invention comprises the following constituents (A) to (G), an inner drive shaft provided with pressure blades, an outer drive shaft provided with extrusion blades, and a rotary table. Each of the above-described shaft seal air seals is applied to a table drive shaft for rotating the shaft. In addition, each of the pressure blade and the extrusion blade is integrally formed as a single component with the bearing boss at the center and the blade (arm and blade body at the tip) extending from the outer periphery. Has been. Each of the pressure blade and the extrusion blade is attached by fitting a square hole formed in the boss portion into a square shaft portion formed in a drive shaft provided with the blade. And, it is most preferable to be a basket-type extrusion granulator characterized in that at least a hopper, a screen, a pressure blade, an extrusion blade, and a rotary table can be detached and disassembled and washed. I can say that.
(A) A cylindrical hopper into which the kneaded material is charged.
(B) A cylindrical screen provided at the bottom of the hopper and having a plurality of holes.
(C) A pressure blade provided inside the hopper and supplying the charged kneaded material downward.
(D) An extrusion blade that is provided inside the screen and rotates in the direction opposite to the pressure blade to extrude the kneaded material from the screen.
(E) A cylindrical outer drive shaft provided with an extrusion blade at the upper end.
(F) A rod-shaped inner drive shaft that is inserted into the outer drive shaft so as to be relatively rotatable, extends further upward from the outer drive shaft, and is provided with a pressure blade at the extension.
(G) A disc-shaped rotary table that is held rotatably below the screen and receives a granulated product that is radially extruded from the screen.
[0028]
In the case of this configuration, the granulated material is opened to every corner of the portion where the granulated material may drop and invade, and it is possible to clean easily and completely. That is, all the main parts that come into contact with the powder can be disassembled, and every corner of the part that comes into contact with the powder can be opened, and can be easily and completely cleaned. In addition, since all the main parts in contact with the powder can be disassembled, these components can be easily dried and sterilized after washing. Furthermore, according to the shaft seal air box which can be disassembled, the kneaded material and the cleaning liquid can be prevented from entering the shaft seal, and the shaft seal can be reliably validated for cleaning. Therefore, it is possible to cope with GMP in pharmaceutical preparations and HACCP in food manufacturing.
[0029]
DETAILED DESCRIPTION OF THE INVENTION
The pressure vane has a truncated cone shape, and the boss and the vane (the boss and the arm and the vane body at the tip thereof) are integrally formed, and the pressure vane is constituted by one component as the pressure vane. The extruded blades also have a truncated cone shape, the boss and the blades (the boss and the arm and the blade body at the tip thereof) are integrally formed, and are configured as a single component as the extruded blade. By these, compared with the conventional structure, for example, the number of parts of the pressure blade is reduced from 12 to 1, and the number of parts of the extrusion blade is reduced from 13 to 1.
[0030]
In addition, a shaft seal air box is provided between the rotary shaft of the pressure blade and the rotary shaft of the extrusion blade that rotates in the opposite direction on the outer side. Seal. Further, a shaft seal air box capable of storing seal air for shaft seal air seal is provided between the rotating shaft of the extrusion blade and the outer disk, and the shaft seal air seal is performed.
[0031]
In addition, a rotary disk is provided on the outer side of the rotary shaft shaft-sealed air box of the extrusion blade, and a rotary table is provided below the rotary table that receives the granulated material radially extruded from the cylindrical screen while rotating. The drive shaft is provided as a single shaft in parallel with the double shaft of the pressure blade and the extrusion blade, and after the removable disk is removed in the vertical direction, the rotary table can be removed in the vertical direction. A shaft seal air box capable of storing seal air for shaft seal air seal is provided between the rotary shaft of the rotary table and the disk on the outside thereof, and shaft seal air seal is performed.
Each shaft seal portion has a structure that can be disassembled by integrating a shaft seal air box, an oil seal, and a bearing.
[0032]
The granulator configured as described above operates as follows.
Each of the pressure blade and the extrusion blade has one component, and management becomes easy, disassembly and assembly become simple, and cleaning becomes easy. Further, since the space between the rotor blades (arms) is reduced, the residue of the material containing the active ingredient is reduced and the recovery rate is increased.
[0033]
Moreover, mixing of the kneaded material into the shaft seal portion in the disassembling operation after the granulation operation and cleaning water are performed by three shaft seal air seals of the pressure blade rotation shaft, the extrusion blade rotation shaft, and the rotary table drive shaft. It becomes possible to prevent intrusion, and operations such as sprinkling cleaning can be performed easily and efficiently. At the same time, the shaft seal is kept dry by seal air to prevent the generation of harmful bacteria. Further, the shaft seal portion can be removed by removing the integrated shaft seal air box, oil seal and bearing during cleaning validation. The granulator configured as described above is compatible with GMP in pharmaceutical preparations and HACCP in food production.
[0034]
【Example】
Hereinafter, the granulator of the present invention will be described in more detail based on examples.
The granulator of the present invention is a basket type extrusion granulator (cylindrical type extrusion granulator).
[0035]
FIG. 1 is a front view of a basket-type extrusion granulator according to the present embodiment. 2 is a plan view thereof, and FIG. 3 is a longitudinal sectional view showing the structure of the upper portion.
[0036]
The granulator according to the present embodiment includes a hopper 1 to which a kneaded product is supplied, a pressure blade 2 that sends the kneaded material supplied to the hopper 1 downward, and a granulator provided below the pressure blade 2. The extrusion blade 3, the substantially cylindrical screen 4 on which the kneaded product is pressed and granulated by the extrusion blade 3, and the rotary table 5 that receives the granulated product extruded from the screen 4 are provided as main parts.
[0037]
The hopper 1 has a substantially cylindrical shape, and an upper end 1a thereof is formed in a tapered surface whose diameter is increased as it goes upward. As shown in FIG. 3, a thick flange 1 b is formed on the outer peripheral surface of the lower end portion of the hopper 1 so as to protrude radially outward, and serves as an attachment portion to the upper end portion of the screen 4.
[0038]
The pressurization blade 2 and the extrusion blade 3 can be rotated by double-shaft rotational drive shafts 6 and 7. The rotary drive shaft is a double shaft in which a round bar-shaped inner drive shaft 7 is inserted inside a cylindrical outer drive shaft 6. An extrusion blade 3 is provided at the upper end portion of the outer drive shaft 6, and a pressure blade 2 is provided at the upper end portion of the inner drive shaft 7. The inner drive shaft 7 extends vertically from the outer drive shaft 6 (7a to 7c and 7d), and the pressurizing blade 2 is provided on the upper extension portion thereof.
[0039]
The double shaft-like rotational drive shafts 6 and 7 are erected vertically and held rotatably, and the rotational drive force is applied from below. In this embodiment, a rotational driving force is applied through a reduction gear 9 provided in the lower gear box 8. In addition, a case 10 and a case lid 11 are provided on the upper portion of the gear box 8, and the drive mechanism portion is covered by these members. And the rotational drive shafts 6 and 7 penetrate these each member, and are extended upwards, and the pressurization blade | wing 2 and the extrusion blade | wing 3 are provided in the extension part.
[0040]
More specifically, as shown in FIG. 1, the lower end portions of the drive shafts 6 and 7 are inserted into the gear box 8. A case 10 is provided at the upper opening of the gear box 8, and the outer drive shaft 6 is rotatably supported by the case 10. That is, a through hole 10a is formed in the case 10 along the vertical direction, and the outer drive shaft 6 is rotatably held via the bearings 12 and 12 at both upper and lower ends of the through hole 10a. The outer drive shaft 6 extends into the gear box 8, and a bevel gear 13 is provided on the outer periphery of the extended portion.
[0041]
On the other hand, the inner drive shaft 7 extends further downward than the outer drive shaft 6, and the extended portion 7 d runs through the gear box 8 and is rotatably supported at the lower end portion of the gear box 8. That is, a cylindrical shaft insertion portion 8a is formed in the lower portion of the gear box 8, and the bearings 14 and 14 are horizontally provided in the shaft insertion portion 8a so as to be separated from each other in the vertical direction. Therefore, the lower end portion of the inner drive shaft 7 is rotatably held by the upper and lower bearings 14 and 14. Moreover, the upper end part of the inner side drive shaft 7 is rotatably hold | maintained by the bearing 16 arrange | positioned in the shaft seal air box 15 so that it may mention later. A bevel gear 17 is provided on the outer periphery of the inner drive shaft 7 above the shaft insertion portion 8a.
[0042]
The bevel gears 13 and 17 fixed to the outer drive shaft 6 and the inner drive shaft 7 are arranged to face each other. The bevel gears 13 and 17 are meshed with a bevel gear 19 held by a motor output shaft 18. Thereby, it is possible to rotate the outer side drive shaft 6 and the inner side drive shaft 7 simultaneously with a common motor. In addition, the outer drive shaft 6 and the inner drive shaft 7 rotate in the opposite directions.
[0043]
As shown in FIG. 3, a substantially disc-shaped case lid 11 is provided on the upper portion of the case 10. This case lid 11 has a shape in which a cylindrical boss 11b is integrally formed at the center of a disc-shaped flange 11a so as to protrude upward. A through hole 11c is formed in the central portion of the boss 11b of the case lid 11 along the vertical direction, and the double shaft-like rotational drive shafts 6 and 7 are passed through the through hole 11c.
[0044]
A disc-shaped base 21 is horizontally held on the upper portion of the boss 11 b of the case lid 11 via a shaft seal air box 20. The shaft seal air box 20 includes a flange 20 a having the same diameter as the boss 11 b of the case lid 11, and the flange 20 a is overlaid on the upper surface of the boss 11 b of the case lid 11 and fixed with bolts 22.
[0045]
Further, a cylindrical boss 20b is integrally formed at the center portion of the flange 20a of the shaft seal air box 20 so as to protrude upward. The upper end outer peripheral portion of the boss 20b is slightly reduced in diameter to form a stepped portion 20c. Accordingly, the disc-shaped base 21 is held by the stepped portion 20c with a central round hole fitted into the reduced diameter portion. That is, a round hole formed in the central portion of the base 21 is fitted into the reduced diameter portion of the boss 20 b and attached with the bolt 23. In the mounted state, the base 21 is disposed horizontally at the upper end of the boss 20b of the shaft seal air box 20. Moreover, the upper end surface of the base 21 is substantially flush with the upper end surface of the shaft seal air box 20. The outer diameter of the base 21 is larger than the boss 11b of the case lid 11 and smaller than the flange 11a.
[0046]
A cylindrical screen 4 is provided on the outer peripheral portion of the base 21 attached in this manner so as to surround the extrusion blade 3. The screen 4 is formed in a thin, substantially cylindrical shape, and the diameter thereof matches the outer diameter of the base 21. In addition, a large number of holes communicating with the inside and the outside are formed in the peripheral side wall of the screen 4. The lower end of the screen 4 is held by the base 21, while the lower end 1 b of the hopper 1 is provided at the upper end. In addition, in order to endure the extrusion pressure at the time of granulation, a halved screen holder 24 is provided on the outer periphery of the screen 4, and the screen 4 is secured to the base by bolts 25 via the screen holder 24. 21 and the hopper 1. The particle size can be adjusted by changing the specifications (plate thickness and hole diameter) of the screen 4.
[0047]
The shaft seal air box 20 provided on the upper portion of the boss 11b of the case lid 11 has through holes 20d and 20e formed at the center as stepped holes. The large-diameter hole 20d formed below has a larger diameter than the through-hole 11c formed in the case lid 11, and is further expanded in diameter at the lower opening. And the oil seal 26 is provided in the lower opening part, and it attaches with the outer side drive shaft 6 maintaining an airtight state. In the shaft seal air box 20 having such a configuration, the large-diameter hole 20d above the oil seal 26 functions as an air reservoir 20d for seal air for shaft seal air seal.
[0048]
The upper end of the boss 20b of the shaft seal air box 20 is formed so that the periphery of the upper opening of the through hole 20e protrudes upward in a substantially conical shape. In this way, the seal air ejection nozzle 20 f for the shaft seal air seal is formed at the upper end of the shaft seal air box 20.
[0049]
The shaft seal air box 20 having such a configuration is supplied with compressed air to the air reservoir 20d, and the seal air is slightly generated between the outer peripheral surface of the outer drive shaft 6 and the inner peripheral surface of the ejection nozzle 20f. It can be ejected upward through a gap. The supply of the sealing air to the air reservoir 20d is performed through an air supply path 27 that extends continuously in the vertical direction from the lower part of the case lid 11 to the middle of the shaft seal air box 20. The air supply path 27 communicates with the air reservoir 20d at the upper end, and is connected to a pump (not shown) through an appropriate pipe at the lower end. Accordingly, the compressed air supplied from the pump can be jetted upward from the jet nozzle 20f at the upper portion thereof through the air reservoir 20d of the shaft seal air box 20 through the air supply passage 27.
[0050]
Similarly to the shaft seal air box 20, a shaft seal air box 15 is also provided at the upper end portion of the outer drive shaft 6. The inner drive shaft 7 extends through the shaft seal air box 15 upward. The shaft seal air box 15 has a cylindrical shape having substantially the same diameter as the outer drive shaft 6 and is fixed to the upper end surface of the outer drive shaft 6 by a bolt 28. The through holes 15a and 15b formed in the center portion of the shaft seal air box 15 are stepped holes. The large-diameter hole 15a formed at the lower side is provided with an oil seal 29 at a step portion at the center in the vertical direction, and is attached to the inner drive shaft 7 while maintaining an airtight state. In addition, a bearing 16 is provided at the lower step portion of the large-diameter hole 15 a, that is, at the lower portion of the oil seal 29. And the upper end part of the inner side drive shaft 7 is rotatably hold | maintained at this bearing 16. As shown in FIG. In the shaft seal air box 15 having such a configuration, the large-diameter hole 15a above the oil seal 29 functions as an air reservoir 15a for seal air for shaft seal air seal.
[0051]
The upper end portion of the shaft seal air box 15 is formed so that the periphery of the upper opening of the through hole 15b protrudes upward in a substantially conical shape. In this way, a jet air nozzle 15 c for shaft seal air seal is formed at the upper end of the shaft seal air box 15.
[0052]
Compressed air is supplied to the air reservoir 15a in the shaft seal air box 15 having such a configuration, and the seal air is a slight amount between the outer peripheral surface of the inner drive shaft 7 and the inner peripheral surface of the ejection nozzle 15c. It can be ejected upward through a gap. The supply of the seal air to the air reservoir 15a is performed through an air supply path 30 communicating with the shaft seal air box 20 provided on the upper portion of the case lid 11.
[0053]
That is, an air supply path 30 is formed in the vertical direction in the outer drive shaft 6 and the shaft seal air box 15 at the upper part thereof, and the air supply path 30 is open to the air reservoir 15a at the upper end. The lower end is open to the outer periphery of the outer drive shaft 6. The lower opening is located at a position corresponding to the air reservoir 20 d of the shaft seal air box 20 above the case lid 11. Therefore, the seal air to the shaft seal air box 15 above the outer drive shaft 6 is supplied via the shaft seal air box 20 above the case lid 11. While the case lid 11 is fixed, the outer drive shaft 6 is a rotating body, but the air reservoir 20d at the top of the case lid 11 is in the entire circumferential direction, so the air supply path 30 of the outer drive shaft 6 is By communicating with the air reservoir 20d, seal air is always supplied to the shaft seal air box 15 above the outer drive shaft 6 regardless of the rotational position of the outer drive shaft 6 (the circumferential position of the air supply path 30). Is done.
[0054]
By the way, the inner drive shaft 7 has a round bar shape slightly reduced in diameter at the portion of the shaft seal air box 15 (7a), and the upper portion of the reduced diameter portion 7a is formed in a prismatic shape 7b. This is the mounting part. Further, a screw portion 7c is formed on the upper portion of the prism portion 7b so as to protrude upward. Accordingly, the pressurizing blade 2 has a wing nut-shaped cap nut 31 after the square hole 2c formed at the center thereof is fitted into the prism portion 7b of the inner drive shaft 7 and then into the screw portion 7c of the inner drive shaft 7. Can be screwed in.
[0055]
Accordingly, the pressure blade 2 is fixed with the boss portion 2 a sandwiched between the upper end surface of the reduced diameter portion 7 a of the inner drive shaft 7 and the lower end portion of the cap nut 31. The cap nut 31 has a substantially conical shape, and its upper end is formed in a substantially hemispherical shape. Further, the cap nut 31 is formed with a screw hole to the screw portion 7c of the inner drive shaft 7 that opens only downward. Further, an operation piece 31a is formed on the outer peripheral surface so as to be rotatable without a tool, and has a wing nut shape.
[0056]
On the other hand, in the substantially cylindrical outer drive shaft 6, the inner through hole 6a is continuously formed with a round hole having a slightly larger diameter than the inner drive shaft 7, but the outer outer peripheral surface has shaft sealed air. The box 20 has a cylindrical shape slightly reduced in diameter (6b), and the upper portion of the reduced diameter portion 6b is formed in a prismatic shape (6c). The prism 6c of the outer drive shaft 6 is an attachment portion for the extrusion blade 3. That is, the extrusion blade 3 is attached by fitting a square hole 3c formed in the center portion thereof into the prism portion 6c of the outer drive shaft 6, and the lower end surface of the boss portion 3a is in a step portion above the reduced diameter portion 6b. Retained. Thereafter, as described above, the pressing blade 2 is attached to the upper portion of the extrusion blade 3 via the annular buffer collar 32, whereby the extrusion blade 3 is positioned.
[0057]
That is, a ring-shaped buffer collar 32 made of a resin such as Teflon (registered trademark) is provided on the upper end surface of the boss 3 a of the extrusion blade 3. On the other hand, in the boss 2a of the pressure blade 2, stepped holes 2d and 2e having substantially frustoconical shapes are formed in the lower portion of the square hole 2c so as to open downward. The shaft seal air box 15 is inserted into the upper diameter expansion hole 2d, and the buffer collar 32 is disposed in the lower diameter expansion hole 2e. Then, the pressing blade 2 is fixed to the inner drive shaft 7 with the cap nut 31 by the method as described above, so that the extrusion blade 3 is also positioned with respect to the pressing blade 2 via the buffer collar 32. become. As a result, the extrusion blade 3 is held by the outer drive shaft 6.
[0058]
Below the base 21, the turntable 5 is rotatably supported so as to extend radially outward from the base 21. The turntable 5 has a substantially disk shape, and a round hole is formed in the center portion into which the boss 11b of the case lid 11 and the shaft seal air box 20 provided on the upper portion thereof are inserted. Support rollers 33 for holding the rotary table 5 are provided on the boss 11b of the case lid 11 at a plurality of locations in the circumferential direction (three locations in this embodiment). That is, the roller support shaft 33a is provided to protrude radially outward from the boss 11b, and the roller 33 is rotatably held on the support shaft 33a via the ball bearing. Therefore, the rotary table 5 is placed and held on the three support rollers 33.
[0059]
A locking portion 5a is formed on the lower surface of the turntable 5 so as to extend downward along the peripheral edge of the central through hole. Therefore, the rotary table 5 is positioned by disposing the roller 33 inside the circumferential locking portion 5a. The outer diameter of the turntable 5 is larger than the base 21 and is about the size of the flange 11 a of the case lid 11.
[0060]
When the turntable 5 is attached, the upper surface of the flange 20a of the shaft seal air box 20 and the upper surface of the turntable 5 are substantially flush with each other. Further, the upper end surface of the turntable 5 protrudes slightly upward on the center side, and a stepped portion 5b is formed. And the extension part 21a below from the outer peripheral part of the base 21 is arrange | positioned in the part of this step part 5b. The gap between the stepped portion 5b and the extending portion 21a is slight, and the powder is placed only on the rotary table 5 on the outer peripheral side of the stepped portion 5b.
[0061]
A driven gear 34 is provided on the lower surface of the turntable 5 along the circumferential direction. In the present embodiment, a substantially short cylindrical member 34 is fixed to the lower surface of the rotary table with a bolt 35, and a gear is formed on the outer peripheral surface thereof. Then, the rotary table 5 is rotationally driven by the drive gear 36 meshed with the driven gear 34. That is, the table drive shaft 37 is provided through the flange 11 a of the case lid 11, and the drive gear 36 is provided at the upper end of the table drive shaft 37. The drive gear 36 is engaged with the driven gear 34 of the rotary table 5. The table drive shaft 37 is rotationally driven by a motor with a speed reducer (not shown) disposed below the table drive shaft 37. The rotational drive force of the table drive shaft 37 can also be obtained from the drive force of a motor that drives the double-shaft rotational drive shafts 6 and 7.
[0062]
Similar to the shaft seal of the outer drive shaft 6 and the inner drive shaft 7, the table drive shaft 37 is also sealed with a shaft seal. In this embodiment, a shaft seal air box 38 is provided above the flange 11 a of the case lid 11, and the table drive shaft 37 extends upward via the flange 11 a and the shaft seal air box 38. The drive gear 36 is provided at the upper end of the extension.
[0063]
The shaft seal air box 38 has the same configuration as that of the upper part of the boss 11 b of the case lid 11. That is, it is substantially cylindrical and is fixed to the upper end surface of the flange 11 a of the case lid 11 by the bolt 39. The through holes 38a and 38b formed in the center portion of the shaft seal air box 38 are stepped holes. The large-diameter hole 38a formed at the lower side is further expanded in diameter at the lower opening, and an oil seal 40 is provided at the stepped portion, and is attached to the table drive shaft 37 while maintaining an airtight state. In the shaft seal air box 38 having such a configuration, the large-diameter hole 38a above the oil seal 40 functions as an air reservoir 38a for seal air for shaft seal air seal.
[0064]
Further, the upper end portion of the shaft seal air box 38 is formed so that the periphery of the upper opening of the through hole 38b protrudes upward in a substantially conical shape. In this manner, the shaft seal air box 38 is formed with an ejection nozzle 38c for seal air for shaft seal air seal at the upper end of the shaft seal air box 38.
[0065]
Compressed air is supplied to the air reservoir 38a in the shaft seal air box 38 having such a configuration, and the seal air is a slight amount between the outer peripheral surface of the table drive shaft 37 and the inner peripheral surface of the ejection nozzle 38c. It can be ejected upward through a gap. The seal air is supplied to the air reservoir 38a through the air supply path 41 guided into the shaft seal air box 38 after passing through the flange 11a of the case lid 11. The air supply paths 27 and 30 to the shaft-sealed air boxes 20 and 15 of the outer drive shaft 6 and the inner drive shaft 7 can be partially shared or the pump can be shared.
[0066]
A substantially cylindrical table cover 42 is provided on the outer periphery of the flange 11 a of the case lid 11 so as to surround the rotary table 5. The table cover 42 includes a peripheral side wall that extends upward from the rotary table 5, and a discharge chute 43 is installed in a part of the notch. A substantially cylindrical material 44 is provided on the inner peripheral surface of the table cover 42. The substantially cylindrical member 44 has a lower end surface provided at a position close to the upper end surface of the turntable 5. The thickness of the substantially cylindrical material 44 is such that the gap between the inner peripheral surface of the table cover 42 and the outer peripheral portion of the rotary table 5 is filled. As for the rotary table 5, the clearance gap between the outer peripheral part and the table cover 42, and the clearance gap between the outer peripheral upper end part and the substantially cylindrical material 44 lower end part are set slightly, respectively, and the granulated material from the screen 4 is The rotary table 5 is surely received.
[0067]
As shown in FIGS. 2 and 3, a scraper 45 is provided on the upper end surface of the rotary table 5 at a position corresponding to the chute 43. The scraper 45 has a substantially rectangular plate shape arranged perpendicular to the rotary table 5. Thereby, the granulated material received by the rotary table 5 is guided to the chute 43 by the scraper 45 and collected.
[0068]
By the way, the extrusion blade 3 fixed to the upper end portion of the outer drive shaft 6 includes a substantially truncated cone-shaped boss portion 3a at the center, and a plurality of blades 3b are radially outwardly provided on the outer peripheral portion of the boss portion 3a. It is provided. In this embodiment, for example, four blades (arm and blade body at the tip thereof) 3b are provided every 90 degrees, and each blade 3b is rotated in the rotational direction (counterclockwise in plan view in this embodiment). It has a bulging curved surface and tapers as it goes radially outward. However, it goes without saying that the number of blades 3b and their shapes can be changed as appropriate.
[0069]
Note that the outer diameter of the extrusion blade 3 including the boss portion 3 a and the blade 3 b is slightly smaller than the inner diameter of the screen 4 and larger than the inner diameter of the hopper 1. In the case of the extrusion blade 3 shown in the drawing, the upper end portion of the boss portion 3a extends slightly upward from the blade 3b. And the said lower side enlarged diameter hole 2e of the boss | hub part 2a of the pressurization blade | wing 2 is put on the extension part in the proximity | contact state. Thereby, the kneaded material from the pressure blade 2 is reliably supplied to the outer peripheral side of the boss portion 3 a of the extrusion blade 3.
[0070]
As described above, the extrusion blade 3 has the boss portion 3a having a truncated cone shape. That is, the outer peripheral portion of the boss portion 3a is formed in a tapered surface whose diameter increases as it goes downward. Needless to say, the inclination angle of the boss 3a is set appropriately, but the opening angle from the apex of the truncated cone is set to about 45 ° to 75 ° (60 ° in the embodiment), for example. Further, the extrusion blade 3 of the present embodiment has a boss portion 3a and a blade 3b (that is, a boss portion, an arm, and a blade body at the tip thereof) integrally formed as one part by casting or welding. Yes.
[0071]
On the other hand, the pressure blade 2 provided at the upper end of the inner drive shaft 7 is also formed in the same manner as the extrusion blade 3. That is, the pressure blade 2 includes a substantially truncated cone-shaped boss portion 2a at the center, and is provided with a plurality of blades 2b extending radially outward from the boss portion 2a. In the present embodiment, two blades 2b are provided at an interval of 180 °, and each blade 2b includes an inclined surface that is inclined in the rotational direction (clockwise in the present embodiment in a plan view) as it goes upward. However, it goes without saying that the number and shape of the blades 2b are appropriately changed. Note that the outer diameter of the pressure blade 2 including the boss portion 2 a and the blade 2 b is slightly smaller than the inner diameter of the hopper 1.
[0072]
Moreover, the boss | hub part 2a of the pressurization blade | wing 2 is made into the truncated cone shape. That is, the boss portion 2a is formed in a tapered surface whose diameter increases as it goes downward. Needless to say, the inclination angle of the boss portion 2a is set appropriately, but the opening angle from the apex of the truncated cone is set to about 45 ° to 75 ° (60 ° in the embodiment), for example. Further, in the pressure blade 2 of this embodiment, the boss portion 2a and the blade 2b (that is, the boss portion, the arm, and the blade body at the tip thereof) are integrally formed by casting, welding or the like in the same manner as the extrusion blade 3 described above. Formed as one part.
[0073]
When using the granulator of the present embodiment configured as described above, the rotary drive shafts 6 and 7 are rotated to rotate the extrusion blade 3 and the pressure blade 2, and the table drive shaft 5 is rotated. Then, the rotary table 5 is rotated. Then, the kneaded material kneaded by the kneader is put into the hopper 1. The charged kneaded material is supplied to the lower extrusion blade 3 by the pressure blade 2. The kneading is also performed by the reverse rotation of the pressure blade 2 and the extrusion blade 3. Then, the kneaded product is pressed against the screen 4 by the extrusion blade 3, granulated into a substantially cylindrical shape, and falls onto the rotary table 5. The granulated material that has fallen on the rotary table 5 moves to the scraper 4 by the rotation of the rotary table 5, and falls to the chute 43 by the scraper 45 and is collected.
[0074]
Here, since the boss | hub part 3a is formed in the substantially truncated cone shape in the extrusion blade 3, the space volume between the arms 3b becomes small compared with the conventional cylindrical boss | hub part. As a result, the residual kneaded material in the granulation chamber after the granulation operation can be reduced, and the recovery rate is improved. Further, the kneaded product can be guided to the entire surface of the screen 4 and granulated uniformly and smoothly from the entire screen 4. That is, by reducing the space volume, it is possible to increase the extrusion pressure on the cylindrical screen 4 and increase the extrusion capacity.
[0075]
FIG. 4 is an exploded sectional view of the upper part of the extrusion granulator of the above embodiment. FIG. 5 is a longitudinal sectional view showing the upper part of the granulator main body after disassembly. FIG. 6 is a view showing the upper part of the rotary drive shafts 6 and 7 after disassembly, and FIG. 7 is a view showing the upper part of the table drive shaft 5 after disassembly.
[0076]
In the case of the granulator of this embodiment, it can be disassembled and washed after the granulation operation. When disassembling, the screen holder 24 is first removed, and the cylindrical screen 4 and the supply hopper 1 are removed. Next, the cap nut 31 is loosened and removed, and the pressure blade 2, the buffer resin collar 32, and the extrusion blade 3 are sequentially extracted upward from the rotary drive shafts 6 and 7. Next, the table cover 42, the discharge chute 43, and the scraper 45 are extracted upward. Next, the base 21 is removed from the case lid 11, and the rotary table 5 with the driven gear 34 is pulled out upward.
[0077]
In this way, the decomposition is completed, and in this disassembled state, all the parts to which the kneaded material and the granulated material have adhered are removed. When the disassembly is completed, as shown in FIG. 5, the lower part of the rotary table 5 where the granulated material may drop from the gap between the rotary table 5 and the table cover 42, that is, the upper surface of the flange 11a of the case lid 11, Fully exposed. Therefore, it is possible to clean completely. That is, not only can each part that has been disassembled and removed be cleaned, but also the remaining side without being disassembled can be easily and reliably cleaned. Each part can be processed in a dryer or sterilizer. The table driving gears 34 and 36 are made of resin and can withstand round washing with a cleaning liquid.
[0078]
In the cleaning operation, before starting decomposition, compressed air is introduced into the air supply passages 27, 30, 41, the air flow is rectified by the air reservoirs 20d, 15a, 38a, and the sealed air outlets 20f, 15c, 38c. Erupt from. Thereafter, cleaning operations such as preliminary cleaning, main cleaning, and rinsing are performed. That is, during disassembly and cleaning (water discharge, etc.), as shown in FIGS. 6 and 7, the outer drive shaft 6 and the case are ejected by blowing air upward from the shaft sealed air boxes 15, 20, and 38. It is possible to prevent powder and cleaning liquid from entering the apparatus from the gap between the lid 11, the gap between the inner drive shaft 7 and the outer drive shaft 6, and the gap between the table drive shaft 37 and the case lid 11, respectively. .
[0079]
Furthermore, the shaft seal portion and the like can be easily dried by ejecting seal air from the shaft seal air boxes 15, 20, and 38 even after cleaning. Moreover, since the shaft seal air boxes 15, 20, and 38 are detachable, they can be removed and the state of cleaning and drying can be easily confirmed.
[0080]
In addition, arrangement | positioning and attachment state of each shaft seal air box 15,20,38 have a labyrinth structure with respect to the approach of kneaded material, and do not require seal air during granulation operation. Moreover, this is even more true since the kneaded material is usually in contact with the powder body itself. That is, if it is only for granulation, it can be said that it is not necessary to seal the shaft originally, but it can be said that the present invention is characterized in that it is intentionally applied as a cleaning measure.
[0081]
The basket type extrusion granulator of the present invention is not limited to the configuration of the above embodiment, and can be changed as appropriate.
For example, in the above embodiment, the bearing 16 is provided in the shaft seal air box 15 above the outer drive shaft 6 and the upper portion of the inner drive shaft 7 is supported by the bearing 16 in rotation. A bearing may be provided in the shaft seal air box 20 above the boss 11 b of the lid 11, and the upper portion of the outer drive shaft 6 may be rotationally supported by the bearing. Further, the same applies to the table drive shaft 37, and a bearing may be provided in the shaft seal air box 38.
[0082]
In the above embodiment, the shaft seal air boxes 15, 20, and 38 are provided at the portion where the shaft seal air seal is desired to be provided. However, the shaft seal air box is integrated with the case lid 11 and the outer drive shaft 6 itself. It may be provided. Further, in addition to the inner and outer drive shafts 6 and 7 and the table drive shaft 37, if there is a rotating shaft, the shaft sealing air seal can be similarly applied to the rotating shaft.
[0083]
Furthermore, in the said Example, the attachment of the pressurization blade | wing 2 and the extrusion blade | wing 3 to the rotational drive shafts 7 and 6 makes the square holes 2c and 3c formed in the boss | hub parts 2a and 3a connect with the rotational drive shafts 7 and 6. As a configuration to be fitted to the prisms 7b and 6c, a quadrangular cross section is adopted as the shape, but it is needless to say that the present invention is not limited to a quadrilateral and other polygons can be adopted.
[0084]
Moreover, in the said Example, although the pressurization blade | wing 2 and the extrusion blade | wing 3 each formed the boss | hub parts 2a and 3a and the arms 2b and 3b integrally as one component, depending on the case, a boss | hub part and an arm And a plate material (blade body) that can be attached to and detached from the arm. In particular, the arm can be provided with a replaceable blade body. In the case where the blade body is attached to the blade tip in a replaceable manner with bolts and nuts, when the blade body is worn, only the blade body needs to be replaced. Moreover, if a plurality of types of blade bodies can be exchanged, appropriate blades can be used depending on the properties of the powder.
[0085]
Moreover, in the said Example, although the extrusion blade 3 and the pressurization blade | wing 2 were each installed only 1 step | paragraph in the upper and lower sides, respectively, it is also possible to make it multistage. Further, as described above, the number and shape of the blades 2 and 3 are appropriately changed depending on the physical properties of the powder.
[0086]
Further, the number of air supply passages 27, 30, 41 for supplying air to the air reservoirs 15a, 20d, 38a of the shaft sealed air boxes 15, 20, 38 takes into account the amount of air blowout and the jet output. Thus, it can be changed as appropriate.
[0087]
【The invention's effect】
As described above in detail, according to the basket type extrusion granulator of the present invention, assembly / disassembly and cleaning are facilitated. In addition, confirmation of cleaning, drying, and the like becomes easy in cleaning validation. Further, the residual amount of raw materials remaining after operation can be reduced.
[Brief description of the drawings]
FIG. 1 is a front view showing an embodiment of a basket-type extrusion granulator according to the present invention, partially showing a cross section and omitting a part thereof.
FIG. 2 is a plan view of the basket type extrusion granulator of FIG. 1;
3 is a longitudinal sectional view showing an upper structure of the basket type extrusion granulator of FIG. 1; FIG.
4 is an exploded cross-sectional view of the upper part of the basket-type extrusion granulator of FIG. 1. FIG.
5 is a longitudinal sectional view showing an upper part of a granulator main body after disassembly of the basket type extrusion granulator of FIG. 1; FIG.
6 is a view showing an upper part of a rotary drive shaft after disassembly of the basket type extrusion granulator of FIG. 1;
7 is a view showing an upper part of a table drive shaft after disassembly of the basket type extrusion granulator of FIG. 1; FIG.
[Explanation of symbols]
1 Hopper
2 Pressure blade
2a Bearing boss
2b Blade (arm and blade body)
2c square hole
3 Extruded blade
3a Bearing boss
3b blade (arm and blade body)
3c square hole
4 screens
5 Rotary table
6 Outer drive shaft (rotary drive shaft)
6c square shaft
7 Inner drive shaft (rotary drive shaft)
7b Square shaft
8 Gearbox
9 Reducer
10 cases
11 Case lid (outer member)
12 Bearing
13 Bevel gear
14 Bearing
15 Shaft sealed air box
15a Large-diameter hole (air reservoir)
15b Through hole
15c jet nozzle
16 Bearing
17 Bevel gear
18 Motor output shaft
19 Bevel gear
20 shaft sealed air box
20d Large-diameter hole (air reservoir)
20e Through hole
20f ejection nozzle
21 base
24 Screen holder
26 Oil seal
27 Air supply path
29 Oil seal
30 Air supply path
31 Cap nut
32 Buffer color
33 Support roller
34 Driven gear
36 Drive gear
37 Table drive shaft
38 Shaft sealed air box
38a Large-diameter hole (air reservoir)
38b Through hole
38c jet nozzle
40 Oil seal
41 Air supply path
42 Table cover
43 Discharge chute
45 scraper

Claims (9)

In a basket-type extrusion granulator that is supplied with a kneaded material from a hopper and granulates by guiding the kneaded material to a cylindrical screen through an extrusion blade,
The rotary drive shaft of the extrusion blade is jetted upward between the inner peripheral surface of the upper end portion of the outer member and the outer peripheral surface of the rotary drive shaft between the outer member through which the rotary drive shaft passes. A basket type extrusion granulator characterized in that a shaft seal air seal can be formed. A cylindrical hopper into which the kneaded material is charged;
A cylindrical screen provided at the bottom of the hopper and having a plurality of holes;
A pressure blade provided inside the hopper and supplying the charged kneaded material downward;
An extrusion blade provided inside the screen, rotating in the opposite direction to the pressure blade, and extruding the kneaded material from the screen;
A cylindrical outer drive shaft provided with an extrusion blade at the upper end, and
A rod-shaped inner drive shaft that is inserted into the outer drive shaft so as to be relatively rotatable, extends further upward from the outer drive shaft, and is provided with a pressure vane at the extension portion;
A basket type extrusion granulator characterized in that a shaft-sealing air seal can be formed by jetting air upward between the inner peripheral surface of the upper end portion of the outer drive shaft and the outer peripheral surface of the inner drive shaft. A cylindrical hopper into which the kneaded material is charged;
A cylindrical screen provided at the bottom of the hopper and having a plurality of holes;
A pressure blade provided inside the hopper and supplying the charged kneaded material downward;
An extrusion blade provided inside the screen, rotating in the opposite direction to the pressure blade, and extruding the kneaded material from the screen;
A cylindrical outer drive shaft provided with an extrusion blade at the upper end, and
A rod-shaped inner drive shaft that is inserted into the outer drive shaft so as to be relatively rotatable, extends further upward from the outer drive shaft, and is provided with a pressure vane at the extension portion;
A case lid that is disposed at the bottom of the extrusion blade and through which a drive double shaft consisting of an outer drive shaft and an inner drive shaft passes,
A basket-type extrusion granulator characterized in that a shaft-sealing air seal can be formed by jetting air upward between the inner peripheral surface of the upper end of the case lid and the outer peripheral surface of the outer drive shaft, or The basket type extrusion granulator according to claim 2. A disc-shaped rotary table that receives a granulated product extruded radially from the cylindrical screen is rotatably held below the screen.
The table drive shaft for rotationally driving the rotary table has an air flow upward between the outer peripheral surface of the upper end portion of the outer member and the outer peripheral surface of the table drive shaft between the outer member through which the table drive shaft passes. The basket-type extrusion granulator according to claim 2 or 3, wherein a shaft-sealed air seal can be formed by jetting the water. The shaft seal air seal is performed via a shaft seal air box in which a through hole through which a shaft seal target rotating shaft is passed,
At the upper end of the shaft seal air box, a jet nozzle for seal air for shaft seal air seal is formed,
The through-hole of the shaft seal air box is a large-diameter hole at the lower portion thereof, which is supplied with seal air for shaft seal air seal and collects the seal air.
The shaft seal air box is attached to the shaft seal target rotating shaft in a hermetic state via a packing at a lower portion of the large-diameter hole. The basket-type extrusion granulator as described. In a basket-type extrusion granulator, a kneaded product is supplied from a hopper via a pressure blade, and the kneaded material is guided to a cylindrical screen via an extrusion blade and granulated.
One or both of the pressure blade and the extrusion blade are formed such that the bearing boss portion at the center and the blade extending from the outer peripheral portion are integrally formed as one part, and the boss portion is below The basket-type extrusion granulator according to any one of claims 2 to 5, or a basket-type extrusion granulator according to any one of claims 2 to 5, wherein the basket-type extrusion granulator is formed in a substantially frustoconical shape with a diameter increasing toward the center. Either or both of the pressure blade and the extrusion blade are attached by detachably fitting a square hole formed in the boss portion into a square shaft portion formed in a drive shaft provided with the blade. The basket type extrusion granulator according to claim 6, A cylindrical hopper into which the kneaded material is charged;
A cylindrical screen provided at the bottom of the hopper and having a plurality of holes;
A pressure blade provided inside the hopper and supplying the charged kneaded material downward;
An extrusion blade provided inside the screen, rotating in the opposite direction to the pressure blade, and extruding the kneaded material from the screen;
A cylindrical outer drive shaft provided with an extrusion blade at the upper end, and
A rod-shaped inner drive shaft that is inserted into the outer drive shaft so as to be relatively rotatable, extends further upward from the outer drive shaft, and is provided with a pressure vane at the extension portion;
A disc-shaped rotary table that is held rotatably below the screen and receives a granulated product that is extruded radially from the screen;
5. Each shaft seal air seal according to claim 2, wherein an inner drive shaft provided with pressure blades, an outer drive shaft provided with extrusion blades, and a table drive shaft that rotationally drives the rotary table, respectively. Is given,
Each of the pressure blade and the extrusion blade is integrally formed as a single part with the bearing boss portion at the center and the blade extending from the outer peripheral portion,
Each of the pressure blade and the extrusion blade is attached by fitting a square hole formed in the boss portion into a square shaft portion formed in a drive shaft provided with the blade,
A basket-type extrusion granulator characterized in that at least a hopper, a screen, a pressure blade, an extrusion blade, and a rotary table can be attached and detached to enable disassembly and cleaning. The extrusion blade is used by being attached to a basket type extrusion granulator that is supplied with a kneaded material from a hopper and guided to the cylindrical screen through the extrusion blade to granulate,
The extrusion blade of the basket type extrusion granulator is characterized in that the central bearing boss portion of the extrusion blade is formed in a substantially truncated cone shape whose diameter is increased as it goes downward.

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