JP5681754B2 - Crusher - Google Patents

Description

  The present invention relates to a pulverizer for pulverizing a material to be processed such as a container (for example, a plastic container such as a plastic bottle or a blow container) made by blow molding or vacuum molding.

There exists a thing disclosed by patent document 1 as a grinder which grind | pulverizes a to-be-processed material.
The pulverizer includes a rotor provided on a casing so as to be rotatable around an axis, a rotary blade blade provided on an outer peripheral side of the rotor, and a fixed outer side of the rotor that is fixed to the casing side. A pulverizer body having a fixed blade for pulverizing the processing material in cooperation with the rotary blade is provided.

The pulverizer includes a screw auger disposed concentrically with the rotor and having one end inserted into the rotor and rotated around an axis to supply a material to be processed into the rotor. .
In this pulverizer, the material to be processed supplied into the rotor by the screw auger is pushed out to the outer peripheral side of the rotor, and the material to be processed is pulverized by the rotating blade blade and the fixed blade on the outer peripheral side of the rotor. Is done.

US Patent US7021576B2

In the conventional pulverizer, the material to be processed is simply compressed with a screw auger and supplied to the inside of the rotor, so the filling rate of the material to be processed inside the rotor is low, The grinding efficiency was not sufficient.
Therefore, in view of the above problems, the present invention can efficiently supply a large amount of the material to be processed into the rotor, and greatly improve the filling rate of the material to be processed in the rotor, so that the processing capacity and the pulverization can be achieved. It is an object to provide a pulverizer capable of greatly improving the efficiency.

The technical means taken by the present invention to solve the technical problems are characterized by the following points.
In the invention according to claim 1, a rotor provided to be rotatable around the axis of the casing, a rotary blade blade provided on the outer peripheral side of the rotor, and positioned on the outer side of the rotor and fixed to the casing side. A fixed blade that pulverizes the material to be processed in cooperation with the rotary blade, and includes a pulverizer body that pulverizes the material to be processed supplied to the inside of the rotor on the outer peripheral side of the rotor,
A screw auger disposed concentrically with the rotor and having one end inserted into the rotor and driven to rotate in a direction opposite to the rotational direction of the rotor to supply the material to be treated into the rotor;
Material to be treated feed inlet side of the crusher body, the coarse grinding means for performing coarse crushing of the treated material prior to the main crushing the material to be treated in the crusher main body provided, the coarse grinding means, to be treated in the rotor A movable groove formed along the inner peripheral surface of the bearing portion on the material supply inlet side so as to intersect the circumferential direction, a bearing portion on the material supply inlet side of the rotor, and a rotor axis A circle fixed blade that is adjacently arranged in the direction, is formed in a concentric ring shape with the rotor, and cannot rotate around the rotor axis;
On the inner peripheral surface of the circle fixed blade, a fixed groove that is formed along the inner peripheral surface so as to intersect in the circumferential direction and can communicate with the movable groove is formed.
The material to be processed that has entered between the movable groove and the fixed groove is coarsely pulverized by a shearing force generated between the movable groove and the fixed groove when the rotor rotates.

In the invention according to claim 2, the rotor provided in the casing so as to be rotatable around the axis, the rotating blade blade provided on the outer peripheral side of the rotor, and the outer side of the rotor being fixed on the casing side. A fixed blade that pulverizes the material to be processed in cooperation with the rotary blade, and includes a pulverizer body that pulverizes the material to be processed supplied to the inside of the rotor on the outer peripheral side of the rotor,
A screw auger disposed concentrically with the rotor and having one end inserted into the rotor and driven to rotate in a direction opposite to the rotational direction of the rotor to supply the material to be treated into the rotor;
A rough pulverization means for coarsely pulverizing the material to be processed before main pulverization of the material to be processed in the pulverizer body is provided on the material supply inlet side of the pulverizer body,
The coarse pulverizing means has a movable groove formed along the inner circumferential surface of the bearing portion of the rotor on the material supply inlet side of the rotor so as to intersect the circumferential direction, and close to the movable groove. And a rough crushing blade provided on the blade of the screw auger,
  The material to be treated that has entered the movable groove is coarsely pulverized by a shearing force generated between the movable groove and the coarse crushing blade when the rotor and the screw auger rotate in the opposite directions.

In the invention according to claim 3, wherein the coarse grinding means has a crushing blade, which is provided on the wing of the screw auger so as to be close to the movable groove,
The material to be treated that has entered the movable groove is coarsely pulverized by a shearing force generated between the movable groove and the coarse crushing blade when the rotor and the screw auger rotate in the opposite directions.

  In the pulverizer according to the present invention, the material to be processed is pushed into the rotor by a screw auger that is driven to rotate, compressed inside the rotor, pushed out to the outer circumferential side of the rotor, and rotated on the outer circumferential side of the rotor. Although the blade blade and the fixed blade are pulverized, when the material to be processed is pushed into the rotor, the material to be processed is roughly pulverized by the coarse pulverization means provided on the material supply inlet side of the pulverizer body. .

In this way, the material to be processed can be supplied into the rotor in a large amount and efficiently by roughly pulverizing the material to be processed by the coarse pulverizing means before main pulverizing the material to be processed in the pulverizer body. By greatly improving the filling rate of the material to be processed, the pulverization capacity and pulverization efficiency can be greatly improved.
Further, since the screw auger is rotationally driven in a direction opposite to the rotational direction of the rotor, the material to be processed filled in the rotor can be efficiently pushed out to the outer periphery side of the rotor.

It is side surface sectional drawing of the principal part of a grinder. It is AA arrow sectional drawing of FIG. It is an expanded sectional view of a crushing part. It is a BB arrow directional cross-sectional view of FIG. It is CC sectional view taken on the line of FIG. It is a side external view of a pulverizer.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 6 shows the overall configuration of the pulverizer 1 that pulverizes the material to be processed such as a PET bottle and a blow container.
The pulverizer 1 includes a pulverizer main body 2 for pulverizing a material to be processed, a processed material conveying device 3 for conveying a material to be processed (crushed material) pulverized by the pulverizer main body 2, and the pulverizer 1. And a processing material supply device 4 for supplying the processing material to the head.

  As shown in FIGS. 1, 2 and 6, the pulverizer body 2 includes a casing 5, a rotor 6 provided in the casing 5 so as to be rotatable around an axis P, and the rotor 6 shown in FIG. A rotor drive motor 7 that is driven to rotate in the direction of the arrow X, a rotary blade blade 8 attached to the outer peripheral side of the rotor 6, and a fixed blade 9 that cooperates with the rotary blade blade 8 to pulverize the material to be treated; , And a pair of screens 10 that cover the rotor 6 from both lateral sides orthogonal to the axial direction.

In this pulverizer 1, the rotor 6 has a hollow shape on the rotor axis P side (inside), and extends from one side of the rotor axis P direction (rotation axis direction) along the rotor axis P direction. A material to be processed is supplied into the rotor 6, and the supplied material to be processed is pulverized on the outer peripheral side of the rotor 6.
In the following description, the lateral direction orthogonal to the rotor axis P direction is referred to as the left-right direction, the front in the transfer direction T of the material to be processed is referred to as the front, and the rear in the transfer direction T of the material to be processed is referred to as the rear. Therefore, the front-rear direction coincides with the rotor axis P direction.

  The casing 5 includes a pair of front and rear main frames 11 that are opposed to each other with a space in the rotor axis P direction, a plurality of connecting frames 12, 13 U, and 13 D that connect the front and rear main frames 11, and the casing 5. A main body door 14 that closes the left and right side surfaces and a canopy 15 that closes the upper surface of the casing 5 are provided. The lower surface side of the casing 5 is opened downward, and the lower end opening of the casing 5 is a discharge port 16 for pulverized material to be processed.

Openings 17 are formed in the middle part of the front and rear main frames 11 in the vertical direction, and cylindrical bearing cases 18F and 18R are fitted and fixed to the openings 17 so as to protrude outward in the front-rear direction.
In the present embodiment, as the connection frames 12, 13 U, and 13 D, four end connection frames 12 that connect the four upper and lower corners of the front and rear main frames 11, and the left and right center sides of the front and rear main frames 11 are provided. A pair of upper and lower center connecting frames 13U and 13D for connecting the upper and lower portions are provided.

The left and right main body doors 14 are, for example, attached to the rear main frame 11 through a hinge so as to be opened and closed, and close the crushing chamber inside the casing 5 so as to be opened and closed.
The rotor 6 includes a pair of front and rear rotary support shaft portions 19F and 19R arranged to face each other at an interval in the rotor axis P direction, and a rotary blade blade mount 20 that connects the front and rear rotary support shaft portions 19F and 19R. And a drum cutter 21 adjacent in the direction of the rotor shaft core P with the rear rotation shaft portion 19R.

  The front rotation shaft portion 19F includes a cylindrical portion 22 concentric with the rotor shaft core P, and a flange portion 23 extending radially outward from the rear end side of the cylindrical portion 22, and includes a front bearing. It is inserted into the case 18F from the rear side, and is supported by the bearing case 18F so as to be rotatable around the rotor shaft core P via the rotor front bearing 24F. The front portion of the cylindrical portion 22 of the front rotation shaft portion 19F protrudes forward from the front bearing case 18F, and a driven pulley 25 is attached and fixed to the protruding portion.

The rear rotation shaft portion 19R includes a cylindrical portion 26 concentric with the rotor shaft core P, and a flange portion 27 extending radially outward from the front end side of the cylindrical portion 26. The bearing case 18R is inserted from the front side, and is supported by the bearing case 18R so as to be rotatable around the rotor core P through a rotor rear bearing 24R.
Further, as shown in FIGS. 2 and 3, a movable groove 28 having a concave cross section formed along the rotor shaft core P direction is formed on the inner peripheral surface 26a of the cylindrical portion 26 of the rear rotating shaft portion 19R. A plurality (six in this embodiment) are formed at equal intervals in the circumferential direction (this is referred to as a first movable groove). Each of the first movable grooves 28 is formed in a penetrating manner from the rear end to the front end of the cylindrical portion 26 of the rear rotation support shaft portion 19R.

  The rotary blade blade mounting base 20 is parallel to the rotor shaft core P so as to connect the flange portions 23 and 27 of the front and rear rotary support shaft portions 19F and 19R to each other at equal intervals in the circumferential direction of the rotor 6. A plurality (five in this embodiment) are provided. The material to be treated supplied to the inside of the rotor 6 can move to the outer peripheral side of the rotor 6 through the space between adjacent rotary blade blade mounts 20 in the circumferential direction of the rotor 6.

  The drum cutter 21 is formed in a ring shape that is concentric with the rotor shaft core P and has an inner diameter that is the same as the inner diameter of the cylindrical portion 26 of the rotary shaft 19R on the rear side. The drum cutter 21 is in contact with the inner ring of the rotor rear bearing 24R that supports the rear rotation support shaft portion 19R from the rear side and is bolted to the cylindrical portion 26 of the rear rotation support shaft portion 19R. It has a function of fixing the rotor rear bearing 24R in the direction of the rotor shaft core P, and also has a shaft sealing function of the oil seal 29 for preventing grease outflow.

The material to be processed passes through the drum cutter 21 and the inner side of the rear rotating shaft 19R and is supplied to the inner side of the rotary blade blade mounting base 20. Accordingly, the rear end side of the drum cutter 21 serves as the material supply inlet 31, and the bearing part of the rotor 6 on the material supply inlet 31 side of the rotor 6 includes the drum cutter 21 and the cylindrical portion 26 of the rotary shaft 19 </ b> R on the rear side. 32.
As shown in FIGS. 3 and 5, a movable groove 33 having a concave cross section formed on the inner peripheral surface 21a of the drum cutter 21 so as to extend from the front end to the rear end in the direction of the rotor axis P (this is referred to as a second groove). A movable groove) is formed. The second movable grooves 33 are provided in a number (six in this embodiment) corresponding to the first movable grooves 28 formed in the cylindrical portion 26 of the rear rotation support shaft portion 19 </ b> R, and are arranged in the circumferential direction of the rotor 6. It is formed at equal intervals. Each second movable groove 33 is formed in an inclined shape that shifts in the rotor rotation direction X toward the rear, and is continuous with the corresponding first movable groove 28. The second movable groove 33 is formed so that the groove width is slightly narrower than that of the first movable groove 28.

As shown in FIG. 6, the rotor drive motor 7 is fixedly mounted on the canopy 15 of the casing 5, an output shaft 34 projects forward, and a drive pulley 35 is attached to the output shaft 34. Rotational power is transmitted from the driving pulley 35 to the driven pulley 25, and the rotor 6 is rotated about the axis P and in the rotational direction indicated by arrow X in FIG.
As shown in FIGS. 1 and 2, the rotary blade blade 8 is attached to the rotary blade blade mounting base 20 so that the blade tip faces the radial outside of the rotor 6.

A pair of left and right fixed blades 9 are attached to the upper and lower central connecting frames 13U and 13D so that the blade edges face the rotor 6 side.
The rotary blade 8 and the fixed blade 9 are provided in parallel with the rotor axis P. Further, the rotary blade 8 and the fixed blade 9 are provided so as to be able to advance and retract, respectively, so that the gap between the blade edges can be optimized.

The material to be treated supplied into the rotor 6 is sheared and pulverized by the cooperation of the rotary blade 8 and the fixed blade 9.
The left and right screens 10 are located outside the rotor 6 diameter of the rotary blade 8 and are formed in an arc shape along the rotation trajectory of the cutting edge of the rotary blade 8, and the lower central portion is connected to the lower central portion connecting frame 13 </ b> U. The rotor 6 is provided so as to extend over the connecting frame 13D from the side. A large number of holes for determining the particle size of the pulverized material to be processed are formed in the screen 10.

  The material to be treated sheared by the rotary blade 8 and the fixed blade 9 moves on the inner surface of the screen 10 together with the rotary blade 8 while sticking to the inside of the screen 10, and is repeatedly crushed and subdivided. The pulverized product that has been pulverized to a size that passes through the holes formed in is passed through the screen 10 and is pushed out of the screen 10. The pulverized processed product pushed out of the screen 10 is prevented from being scattered by the left and right main body doors 14, the main frame 11 and the canopy 15, and is guided to the discharge port 16 at the lower end of the casing 5.

  Each screen 10 is mounted and held on a screen receiver 36. The screen receiver 36 is bolted to the upper central connection frame 13U at the upper part and is bolted to the lower central connection frame 13D at the lower part. . Further, the lower portion of each screen receiver 36 is attached to the lower central connecting frame 13D via a hinge 37 so as to be swingable about the front-rear axis.

Accordingly, the main body door 14 is opened, the bolts fixing the upper and lower portions of the screen receiver 36 are removed, and the screen 10 is swung downward together with the screen receiver 36 (see the phantom line in FIG. 2). Maintenance such as cleaning of the blade 8 and the fixed blade 9 and replacement of the blade can be easily performed.
As shown in FIG. 6, the processed material transfer device 3 is provided with a discharge duct 38 having one end connected to the discharge port 16 of the casing 5 of the pulverizer body 2, and the other end of the discharge duct 38. And a blower 39 that sucks the pulverized material discharged from the discharge port 16 of the machine body 2.

The pulverized processed material sucked by the blower 39 is discharged from the air exhaust port 39a of the air blower 39, and is sent to a storage container or the like by a guide duct (not shown) connected to the air exhaust port 39a.
As shown in FIG. 1, the processing material supply device 4 is driven to rotate around an axis so as to feed the processing material into the pulverizer 1 (inside the rotor 6), and the processing material is supplied. A material input case 42, a hopper 43 installed on the material input case 42, and a screw drive motor 44 that rotationally drives the screw auger 41.

  The screw auger 41 includes a shaft portion 45 and blades 46 provided on the outer periphery of the shaft portion 45 in a spiral shape along the axial direction. The screw auger 41 is arranged concentrically with the axis P of the rotor 6, and the front side (one end side in the axis P direction) is inserted into the rotor 6. Further, the supported portion 47F on the front side of the shaft portion 45 of the screw auger 41 is inserted into the rotation support shaft portion 19F on the front side of the rotor 6, and the shaft is connected to the front rotation support shaft portion 19F via the auger front bearing 48F. The core P is supported so as to be relatively rotatable.

Further, a taper portion 49 is formed at the front portion of the shaft portion 45 of the screw auger 41 and is located on the rear side of the supported portion 47F on the front side. Yes.
The rear part of the screw auger 41 is inserted into the material charging case 42. The supported portion 47R on the rear side of the shaft portion 45 of the screw auger 41 is supported by a bearing case 50 provided on the rear surface side of the material charging case 42 so as to be rotatable around the axis P through an auger rear bearing 48R. Yes.

  The blades 46 of the screw auger 41 are provided from the rear end of the material charging case 42 to the rear end of the tapered portion 49. The blade 46 has a larger outer diameter and pitch in the portion inserted in the material charging case 42 than in the portion inserted in the rotor 6. Thereby, the feed amount of the material to be processed by the screw auger 41 is secured. Conversely, the portion of the blade 46 inserted into the rotor 6 has a smaller outer diameter and pitch than the portion inserted into the material charging case 42. This optimizes the transportability and compression filling condition of the material to be processed.

  As shown in FIGS. 4 and 5, the blade 46 of the screw auger 41 is provided with a roughing blade 51 positioned at a position corresponding to the drum cutter 21. The crushing blade 51 is made of a plate material, and is disposed along the inclination direction of the blade 46 of the screw auger 41, and overlaps the blade 46 so as to protrude from the blade 46 to the outside of the diameter of the screw auger 41. Has been bolted. Further, the outer surface 51 a of the screw auger 41 is formed in an arc shape along the inner peripheral surface 21 a of the drum cutter 21, and the inner peripheral surface 21 a of the drum cutter 21 (second movable). It is provided so as to be close to the groove 33).

  The material charging case 42 is located behind the pulverizer body 2 and is disposed adjacent to the rear bearing case 18R in the direction of the rotor axis P. An upper opening-like charging port 52 is formed on the upper end side of the material charging case 42. In addition, a cylindrical connection portion 53 connected to the bearing case 18R on the rear side of the pulverizer body 2 is formed in the lower portion on the front side of the material charging case 42, and a ring-shaped connection portion 53 is formed on the inner peripheral side of the connection portion 53. A circle fixed blade 54 is attached and fixed.

  The circle fixed blade 54 is disposed adjacent to the drum cutter 21 (the bearing portion 32 of the rotor 6 on the material supply inlet 31 side of the rotor 6) in the direction of the rotor axis P and is concentric with the rotor 6. . Further, since the circle fixed blade 54 is fixed to the material charging case 42, the circle fixed blade 54 cannot rotate around the rotor shaft core P. Further, the screw auger 41 is inserted through the circle fixed blade 54, and the inner peripheral side of the circle fixed blade 54 is a processing material feed port 55. The processing material delivery port 55 communicates with the processing material supply inlet 31 of the pulverizer body 2.

As for the inner peripheral surface 54a of the circle fixed blade 54, the front part is formed in the same diameter as the inner peripheral surface 21a of the drum cutter 21, and the middle part and the rear part are directed rearward (backward in the material transfer direction T). It is formed in a tapered shape that expands in diameter.
As shown in FIG. 5, a fixing groove 56 is formed on the inner peripheral surface 54 a of the circle fixing blade 54. The fixed groove 56 is formed so as to extend from one end to the other end of the circle fixed blade 54 in the axial center P direction, and has a concave cross section that can communicate with the second movable groove 33. The fixed grooves 56 are formed in a number (six in this embodiment) corresponding to the second movable grooves 33 formed in the drum cutter 21 and are formed at equal intervals in the circumferential direction of the circle fixed blade 54. ing. As with the second movable groove 33, each fixed groove 56 is formed in an inclined shape that shifts in the rotor rotation direction X toward the rear. The groove width of the fixed groove 56 is the same as the groove width of the second movable groove 33.

The hopper 43 has an upper and lower opening shape, is connected to the upper end side of the material charging case 42, and its lower end opening communicates with the charging port 52 at the upper end of the material charging case 42, and is charged from the upper end of the hopper 43. The processed material is supplied into the material charging case 42 through the charging port 52.
The screw drive motor 44 (with an on-axis reduction gear) is attached and supported to the bearing case 50 on the rear surface of the material charging case 42 via the motor base 40 and is connected to the rear end of the shaft portion 45 of the screw auger 41. The screw auger 41 is rotationally driven directly and independently of the rotor 6 in a direction opposite to the rotor rotation direction X (auger rotation direction) indicated by an arrow Y in FIG.

  In the pulverizer 1 configured as described above, the material to be processed supplied into the material charging case 42 is transferred forward (processed material transfer direction T) by the screw auger 41 and is forced into the rotor 6. It is. The material to be processed that has been pushed into the rotor 6 is compressed on the inner peripheral side of the rotor 6 by the rotation of the screw auger 41, and the conveyance path is changed from the rotor axis P direction to the radial direction of the rotor 6. It is continuously and quantitatively extruded from the gap between the blade blade mounts 20 to the outer peripheral side of the rotor 6. By rotating the rotor 6 and the screw auger 41 in opposite directions, the discharge property of the material to be processed in the radial direction of the rotor 6 is improved.

As described above, the material to be processed extruded to the outer peripheral side of the rotor 6 is sheared and pulverized by the rotary blade 8 and the fixed blade 9 on the outer peripheral side of the rotor 6.
On the other hand, part of the material to be processed that is pushed into the rotor 6 is fixed on the material supply inlet 31 side of the rotor 6, the fixed groove 56 of the circle fixed blade 54, the second movable groove 33 of the drum cutter 21, and the rear side. Enters the first movable groove 28 of the rotation support portion 18 </ b> R, passes through the grooves 56, 33, and 28, and moves toward the center in the axial direction of the rotor 6. A part of the material to be processed passes through the fixed groove 56 and the movable grooves 28 and 33, so that a propulsive force in the direction of the axis P of the screw auger 41 is obtained.

  Further, since the circle fixed blade 54 (fixed groove 56) cannot rotate and the drum cutter 21 (second movable groove 33) rotates in the rotor rotation direction X, the material to be processed is fixed groove 56, movable groove 28, The material to be processed that has penetrated between the fixed groove 56 and the second movable groove 33 when passing through the 33 is a rear end side of the second movable groove 33 and a portion 57 on the rear end side of the rotor rotational direction X (see FIG. 5). ) And a portion 58 (see FIG. 5) on the front end side of the fixed groove 56 and on the front end side in the rotor rotation direction, and is roughly pulverized.

  Further, since the crushing blade 51 and the movable grooves 28 and 33 rotate in opposite directions, when the material to be processed passes through the fixed groove 56 and the movable grooves 28 and 33, the fixed groove 56 and the movable grooves The material to be treated that has penetrated 28 and 33 includes an edge portion 59 (see FIG. 4) on the front end side in the auger rotation direction Y of the crushing blade 51 and an edge portion on the rear end side in the rotor rotation direction X of the second movable groove 33. 60 (see FIG. 4) and sheared by a shearing force generated between the two and 60 (see FIG. 4).

  As described above, before main processing of the material to be processed by the pulverizer body 2, the material to be processed is roughly pulverized by the fixed groove 56 and the second movable groove 33, and the roughing blade 51 and the second movable material are moved. Since the material to be processed is also roughly pulverized by the grooves 33, the compression rate and the filling rate of the material to be processed filled in the rotor 6 are increased, and the material to be processed can be supplied into the rotor 6 in a large amount and efficiently. Further, by greatly increasing the filling rate of the material to be processed inside the rotor 6, the pulverization processing capacity and the pulverization efficiency can be greatly improved.

  In the pulverizer 1 of the present embodiment, the screw auger 41 partially inserted into the rotor 6 is rotated in the direction opposite to the rotation direction X of the rotor 6, and the material to be processed is placed inside the rotor 6. Since the material to be processed is roughly pulverized on the material supply inlet 31 side of the rotor 6, the pulverizer 1 having a compact machine size and a very small installation space can be provided.

Further, since the screw auger 41 is rotationally driven in the direction Y opposite to the rotational direction X of the rotor 6, the material to be processed filled in the rotor 6 can be efficiently pushed out to the outer peripheral side of the rotor 6.
In addition, this invention is not limited to the said embodiment, A various design change is possible. For example, in the present embodiment, the first movable groove 28 and the second movable groove 33 are arranged so as to intersect the inner peripheral surface of the bearing portion 32 of the rotor 6 on the material supply inlet 31 side in the circumferential direction. Although it is a movable groove formed along the peripheral surface, the cylindrical portion 26 of the rear rotation support shaft portion 19R is extended rearward to connect the cylindrical portion 26 and the circle fixed blade 54 in the direction of the rotor axis P. So that the material to be treated is sheared by the movable groove 28 on the inner peripheral surface 26a of the cylindrical portion 26 of the rotary shaft 19R on the rear side and the fixed groove 56 on the inner peripheral surface 54a of the circle fixed blade 54 (see FIG. Coarse pulverization). In this case, since the drum cutter 21 is not provided, a collar for fixing the rotor rear bearing 24R is provided on the outer peripheral side of the cylindrical portion 26 of the rear rotation support shaft portion 19R by screwing.

In the present embodiment, the material to be treated is roughly pulverized by the roughing blade 51 and the movable groove 33 of the inner peripheral surface 21a of the drum cutter 21, but the roughing blade 51, the first movable groove 28, The material to be treated may be coarsely pulverized.
Therefore, the material to be processed supply inlet 31 of the rotor 6 before the main material is pulverized by the pulverizer body 2 by the first movable groove 28, the second movable groove 33, the fixed groove 56 and the rough crushing blade 51. Coarse pulverizing means for coarsely pulverizing the material to be processed is configured on the side.

  In the present embodiment, six first movable grooves 28, two second movable grooves 33, and fixed grooves 56 are provided, but it is sufficient that at least one of each is provided. Further, the second movable groove 33 and the fixed groove 56 may be formed in the direction of the rotor axis P (that is, may not be inclined).

2 Crusher body 6 Rotor 8 Rotating blade blade 9 Fixed blade 21a Inner peripheral surface (inner peripheral surface of bearing portion of rotor on material supply inlet side)
26a Inner peripheral surface (inner peripheral surface of the bearing portion of the rotor to be processed material supply inlet side)
28 Movable groove (first movable groove)
31 Processed Material Supply Inlet 32 Rotor Bearing Portion of Processed Material Supply Inlet 33 Movable Groove (Second Movable Groove)
41 Screw auger 51 Crush blade 54 Circle fixed blade 54a Inner peripheral surface of circle fixed blade 56 Fixed groove X Rotor rotation direction Y Screw auger rotation direction

Claims (3)

A rotor provided on the casing so as to be rotatable around the axis, a rotary blade blade provided on the outer peripheral side of the rotor, and positioned on the outer side of the rotor and fixed to the casing side, and the material to be processed is A fixed blade that pulverizes in cooperation with the rotary blade blade, and includes a pulverizer body that pulverizes the material to be processed supplied to the inside of the rotor on the outer peripheral side of the rotor;
A screw auger disposed concentrically with the rotor and having one end inserted into the rotor and driven to rotate in a direction opposite to the rotational direction of the rotor to supply the material to be treated into the rotor;
A rough pulverization means for coarsely pulverizing the material to be processed before main pulverization of the material to be processed in the pulverizer body is provided on the material supply inlet side of the pulverizer body ,
The coarsely pulverizing means includes a movable groove formed along the inner peripheral surface of the bearing portion of the rotor on the material supply inlet side of the rotor so as to intersect the circumferential direction, and a material to be processed of the rotor A circle fixed blade that is arranged adjacent to the bearing portion on the supply inlet side in the rotor axial direction, is formed in a concentric ring shape with the rotor, and cannot rotate about the rotor axial center,
On the inner peripheral surface of the circle fixed blade, a fixed groove that is formed along the inner peripheral surface so as to intersect in the circumferential direction and can communicate with the movable groove is formed.
A pulverizer characterized in that the material to be treated that has entered between the movable groove and the fixed groove is coarsely pulverized by a shearing force generated between the movable groove and the fixed groove when the rotor rotates . A rotor provided on the casing so as to be rotatable around the axis, a rotary blade blade provided on the outer peripheral side of the rotor, and positioned on the outer side of the rotor and fixed to the casing side, and the material to be processed is A fixed blade that pulverizes in cooperation with the rotary blade blade, and includes a pulverizer body that pulverizes the material to be processed supplied to the inside of the rotor on the outer peripheral side of the rotor;
A screw auger disposed concentrically with the rotor and having one end inserted into the rotor and driven to rotate in a direction opposite to the rotational direction of the rotor to supply the material to be treated into the rotor;
A rough pulverization means for coarsely pulverizing the material to be processed before main pulverization of the material to be processed in the pulverizer body is provided on the material supply inlet side of the pulverizer body,
The coarse pulverizing means has a movable groove formed along the inner circumferential surface of the bearing portion of the rotor on the material supply inlet side of the rotor so as to intersect the circumferential direction, and close to the movable groove. And a rough crushing blade provided on the blade of the screw auger,
Wherein the treated material that has entered the movable groove, the rotor and the flour grinder characterized in that coarsely pulverized by shearing force generated between the movable groove and cracking blades by the screw auger is rotated in the reverse direction. The coarse crushing means has a crushing blade, which is provided on the wing of the screw auger so as to be close to the movable groove,
The material to be treated which has entered into the movable groove to claim 1, characterized in that the coarsely pulverized by shearing force generated between the movable groove and cracking blades by the rotor and the screw auger is rotated in the reverse direction The grinder described.

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