JP2008173585A - Friction grain polishing roll and friction grain polishing machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a friction grain polished roll capable of easily processing a roll part, and a friction grain polished machine. <P>SOLUTION: In the friction grain polished roll 56, the roll part 64 is constructed by a plurality of axial divisions 64A, a parallel protrusion 56A is attached to the periphery of the roll part 64, and the plurality of divisions 64A is connected. Thus, even if the roll part 64 is axially long, the respective divisions 64A can be made axially short, the respective divisions 64A can easily be processed, and the roll part 64 is easily processed. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a friction milling roll in which the grains in the friction milling mill are friction milled by being arranged and rotated inside the friction milling mill, and a friction mill equipped with the friction milling roll. Related to grain machine.

  As the friction cereal roll, there is one in which a plurality of protrusions are attached along the axial direction on the outer periphery of a cylindrical roll portion (for example, see Patent Document 1).

However, in this frictional grain roll, the roll part is integrated. For this reason, especially in a large-sized friction milling roll for business use, the roll part has a long shape in the axial direction. Thereby, it becomes difficult to process a roll part, and it becomes high cost.
Japanese Patent No. 3012070

  In view of the above facts, an object of the present invention is to obtain a frictional grain roll and a frictional grain machine that can easily process the roll part.

  The friction cereal roll according to claim 1 comprises an outer periphery, a roll part configured by a plurality of divided parts divided in an axial direction, and an outer periphery of the roll part, and is attached to the outer periphery of the roll part And a corn protrusion that connects the plurality of divided portions, and is arranged and rotated inside a cylindrically shaped frictional sperm so that the grains in the frictional sperm are frictionally refined. Cerealed.

  The friction pulverizer according to claim 2 is configured such that the frictional pulverization cylinder in a cylindrical shape and the friction pulverization pulverizer are arranged inside the friction pulverization pulverizer and rotated so that the grains in the friction pulverization varieties are rubbed. Friction cereal roll to be crushed, roll part constituted by a plurality of divided parts divided in the axial direction, constituting the outer periphery of the friction cereal roll, protruding from the outer periphery of the roll part, the roll part And a cereal projection that connects the plurality of divided portions.

  In the friction flour roll according to claim 1, the roll portion constitutes the outer periphery, and the grain protrusion protrudes from the outer periphery of the roll portion, and is disposed inside the friction milling tube in a cylindrical shape. By rotating, the grains in the friction milling cylinder are friction milled.

  Here, the roll part is comprised by the some division | segmentation part divided | segmented into the axial direction, and a cereal protrusion is attached to the outer periphery of a roll part, and the some division | segmentation part is connected. For this reason, even if a roll part is a shape long in an axial direction, each division part can be made into a shape short in an axial direction, and each division part can be processed easily. Thereby, a roll part can be processed easily.

  In the friction pulverizer according to claim 2, the roll portion constitutes the outer periphery of the friction cereal roll, and the grain protrusion protrudes from the outer periphery of the roll portion, so that the inside of the cylindrical friction mill The frictional grain roll is disposed on the frictional grain roll, and the frictional grain roll is rotated, whereby the grain in the frictional milling cylinder is frictionally refined.

  Here, the roll part is comprised by the some division | segmentation part divided | segmented into the axial direction, and a cereal protrusion is attached to the outer periphery of a roll part, and the some division | segmentation part is connected. For this reason, even if a roll part is a shape long in an axial direction, each division part can be made into a shape short in an axial direction, and each division part can be processed easily. Thereby, a roll part can be processed easily.

  Hereinafter, embodiments will be described and embodiments of the present invention will be described. In the present embodiment, a vertical grinding friction integrated grain refiner 10 as shown in FIGS. 1 and 2 will be described as an example of the friction grain refiner according to the present invention.

  The vertical grinding-friction-integrated grain refiner 10 includes a case 12, and an upper partition frame 14, a lower partition frame 18, and a horizontal partition base 20 are installed on the case 12 in this order from the top.

  A hollow vertical rotation main shaft 22 is erected inside the case 12, and the vertical rotation main shaft 22 is rotatably supported by a vertical fixed cylinder portion 26 fixed to the horizontal partition 20. A lower end of the vertical rotation main shaft 22 protrudes from the horizontal partition 20, and a passive pulley 28 is fixed to the lower end of the vertical rotation main shaft 22. The passive pulley 28 is connected to a motor (not shown) via a belt (not shown).

  A plurality of blow holes 22A are formed in the peripheral surface of the lower part of the vertical rotation main shaft 22, and a blow cylinder 30 is attached to the vertical fixed cylinder portion 26 corresponding to the blow holes 22A. The blow cylinder 30 is connected to a blower (not shown), and a blow chamber 32 is formed between the peripheral surface of the lower part of the vertical rotation main shaft 22 and the inner wall of the vertical fixed cylinder part 26. In addition, a plurality of blast holes 22B (see FIG. 3) are formed on the circumferential surface of the substantially central portion in the axial direction of the longitudinally rotating main shaft 22 and are blown by a blower and blown through the blower cylinder 30 and the blower chamber 32. Air blown into the interior (hollow portion) of the longitudinally rotating main shaft 22 from 22A is ejected from this blast port 22B.

  The upper part of the vertical rotation main shaft 22 protrudes from the upper partition frame 14 of the case 12, and a fixing screw 50 (roll pressing cap) is screwed to the upper end of the vertical rotation main shaft 22.

  Above the case 12, a cylindrical grinding part 24 for grinding and graining the rice grains is provided. The lower end of the grinding portion 24 is fixed to the upper partition frame 14 of the case 12, and the upper portion of the longitudinal rotation main shaft 22 is disposed inside the grinding portion 24. A forced feeding cylinder 25 for feeding rice grains (brown rice) as grains is connected and fixed to the grinding unit 24.

  The grinding unit 24 includes a grinding cereal roll 27, a grinding cereal cylinder (exfoliating cylinder) 29 located on the outer peripheral side of the grinding cereal roll 27, and an upper end on the inner peripheral side of the grinding cereal roll 27. A rotating cylinder 31 is provided. A passive pulley 33 is attached to the outer peripheral side of the lower end portion of the rotating cylinder 31, and a bearing 35 is provided between the inner periphery of the rotating cylinder 31 and the outer periphery of a cereal sending cylinder 34 described later. It can be rotated around the grain 34. Between the grinding grain roll 27 and the grinding grain cylinder 29 is a grinding grain chamber 36. In the grinding unit 24, the rice grains from the forced supply cylinder 25 are supplied from the lower end, and are fed from the upper part after grinding.

  Inside the grinding part 24, a cerealing part 37 for sending the rice grains downward is provided. The rice grain fed from the grinding part 24 flows into the cerealing part 37 from above.

  The cerealing portion 37 includes a cerealing cylinder 34 that supports the bearing 35 from the inside, and a cerealing roll that is positioned inside the cerealing cylinder 34 and is rotatable integrally with the longitudinally rotating main shaft 22 as described later. 40 is provided. A cerealing chamber 42 is provided between the cerealing roll 40 and the cerealing cylinder 34, and a single line for feeding rice grains downward by rotation of the cerealing roll 40 on the outer peripheral surface of the cerealing roll 40. A threshing spiral 40R is formed.

  Below the cerealing part 37, a friction part 38 for polishing the rice grains fed from the cerealing part 37 (friction refined) is provided.

  In the friction part 38, a substantially cylindrical frictional grain roll 56 is fitted to the longitudinally rotating main shaft 22 below the cerealing roll 40, and the frictional pulverizing roll 56 is integrally formed on the same axis as the cerealing roll 40. It is connected. On the outer peripheral surface of the friction pulverizing roll 56, long rectangular plate-like parallel ridges 56 </ b> A serving as blasting protrusions are attached to a plurality of locations (three locations in the present embodiment). They are parallel to each other along the axial direction of the milling roll 56. In addition, a plurality of circular blast holes 56 </ b> B are formed through the peripheral surface of the frictional pulverizing roll 56 on the side opposite to the direction of the frictional pulverizing roll 56 of the parallel protrusion 56 </ b> A.

  As shown in detail in FIGS. 3 to 6, the frictional grain roll 56 is provided with a cylindrical roll part 64 (main body part), and the roll part 64 constitutes the outer periphery of the frictional grain roll 56. ing. The roll part 64 is configured by a plurality (two in the present embodiment) of cylindrical division parts 64A, and the plurality of division parts 64A divide the roll part 64 in the axial direction. A lower end of the upper divided portion 64A is rotatably inserted and fitted to an upper end of the lower divided portion 64A, and movement to the lower divided portion 64A side of the upper divided portion 64A is prevented. A cylindrical boss 66 serving as a drive portion is formed at the lower end of the lowermost divided portion 64A at the inner peripheral side portion, and a rotation locking portion is formed on the inner peripheral surface of the boss 66. A rectangular columnar keyway 66A is formed along the axial direction. The boss 66 is fitted with the vertical rotation main shaft 22, and the key groove 66 </ b> A is fitted with a key protrusion (not shown) constituting a rotation locking portion fixed to the vertical rotation main shaft 22. Thus, the lowermost divided portion 64 </ b> A is non-rotatably fitted to the vertical rotation main shaft 22 so as to be rotatable integrally with the vertical rotation main shaft 22.

  On the outer peripheral surface of the roll portion 64, a long rectangular column-shaped attachment groove 74 as an attachment portion is formed along the axial direction, and the parallel protrusion 56A is inserted and fitted into the attachment groove 74, and the roll In a state of protruding from the outer periphery of the part 64, the roll part 64 is attached by fastening a plurality of bolts 76 (five in the present embodiment). Fastened portions by bolts 76 of parallel ridges 56A are arranged in each divided portion 64A, and each divided portion 64A is connected by parallel ridges 56A. As a result, the rotational force (driving force) transmitted from the vertical rotation main shaft 22 to the lowermost divided portion 64A can be transmitted to the upper divided portion 64A from the lowermost divided portion 64A via the parallel protrusion 56A. The vertical rotation main shaft 22, the roll portion 64 (each divided portion 64A) and each parallel protrusion 56A are integrally rotatable, and vibration between the divided portion 64A and the divided portion 64A is prevented by the parallel protrusion 56A. Has been.

  The downward movement of the roll portion 64 (lowermost division portion 64A) with respect to the longitudinal rotation main shaft 22 is prevented, and the lower end of the cerealing roll 40 is inserted into the upper end of the roll portion 64 (uppermost division portion 64A). Combined, the movement of the cerealing roll 40 toward the frictional pearling roll 56 is prevented. Thereby, as described above, the fixing screw 50 (roll pressing cap) is screwed onto the upper end of the vertical rotation spindle 22, and the cerealing roll 40 is sandwiched between the fixing screw 50 and the roll portion 64. The relative rotation between the roll portion 64 and the cerealing roll 40 is prevented, and the longitudinal rotation main shaft 22, the frictional pulverizing roll 56, and the cerealing roll 40 are integrally rotatable.

  Around the frictional grain roll 56, a frictional grain cylinder (removal cylinder) 58 is provided, and the frictional grain cylinder 58 is disposed between the upper partition frame 14 and the lower partition frame 18. The shape of the friction milling cylinder 58 is, for example, a substantially hexagonal (deformed dodecagonal) cylinder. A friction grain chamber 60 is formed between the friction milling cylinder 58 and the friction milling roll 56. Further, a large number of friction removal holes 58 </ b> A are formed on the peripheral surface of the frictional milling cylinder 58. Here, when the longitudinally rotating main shaft 22 is rotated and the frictional polishing roll 56 is rotated integrally, the rice grains in the frictional polishing chamber 60 are polished while being stirred by the plurality of parallel protrusions 56A.

  A milling cylinder frame 62 is provided around the frictional milling cylinder 58, and a cylindrical outer cylinder 68 is provided around the milling mill frame 62. A scissor discharge pipe 70 is fixed to the side wall of the outer cylinder 68, and a removal chamber 72 is formed inside the outer cylinder 68. The soot discharge pipe 70 is connected to a blower (not shown).

  A friction valve 80 is provided below the frictional pulverizing roll 56 to form a lower wall of the frictional pulverizing chamber 60 and to impart cereal resistance to the rice grains.

  The longitudinally rotating main shaft 22 is inserted into the resistance valve 80 so as to be movable in the vertical direction, and the resistance valve 80 can open and close the lower end of the friction brewing chamber 60. The resistance valve 80 is supported at one end of the resistance valve link frame 82 so as to be relatively rotatable and relatively slidable. A middle portion in the longitudinal direction of the resistance valve link frame 82 is rotatably supported by a support base 100 described later. ing. The other end of the resistance valve link frame 82 is connected to a lower motor (milling resistance adjusting motor) 96 via a tension coil spring 94. By operating this motor 96, the tension coil spring 94 is connected to the resistance valve link. The biasing force (pressure) applied to the resistance valve 80 is adjusted via the frame 82, and the resistance valve 80 closes the grain outlet 60A with this biasing force. Thereby, resistance for milling is imparted to the rice grains in the friction brewing chamber 60, and the lower end of the friction mashing chamber 60 is opened at an opening corresponding to the pressing force by which the rice grains press the resistance valve 80 downward. Is done.

  A funnel-shaped discharge disc 98 is fitted to the vertical rotation main shaft 22 below the resistance valve 80, and the discharge disc 98 rotates integrally with the vertical rotation main shaft 22. The discharge board 98 is disposed in a bowl-shaped support base 100 formed integrally with the vertical fixed cylinder portion 26. A discharge basket 102 is fixed to the support table 100, and the rice grains that have finished milling and have fallen into the support table 100 from the friction graining chamber 60 are discharged out of the case 12 from the discharge basket 102 by the rotating discharge disk 98. It is the composition which is done.

(Function, effect)
Next, the operation and effect of the present embodiment will be described.

  In the vertical grinding friction-integrated cerealing apparatus 10, a vertical rotation main shaft 22 is rotated by a motor (not shown) via a belt (not shown) and a passive pulley 28, and the cerealing roll 40 connected on the same axis, The friction grain roll 56 and the discharge disc 98 are rotated together. Further, the rotating cylinder 31 and the grinding roll 27 are rotated via a belt and a passive pulley 33 by another motor (not shown). In this state, the rice grains (brown rice) are supplied to the forced feeding cylinder 25 via the cereal tube 16. The supplied rice grains are fed to the grinding unit 24 and ground by the grinding unit 24.

  The rice grains that have undergone the grinding process in the grinding unit 24 are sent to the cerealing unit 37 and further sent to the friction unit 38.

  The rice grains sent to the friction unit 38 are conveyed into the friction cereal chamber 60 and are agitated by the plurality of parallel protrusions 56 </ b> A of the friction cereal roll 56. As a result, the glutinous layer on the surface of the rice grain is removed by the frictional force acting between the rice grains.

  Further, by operating the motor 96, the urging force that the tension coil spring 94 applies to the resistance valve 80 via the resistance valve link frame 82 is adjusted. Therefore, the resistance valve 80 gives a controlled resistance to the rice grains in the friction cereal chamber 60.

  This resistance valve 80 opens the grain outlet 60 </ b> A at an opening degree corresponding to the pressing force of the rice grains in the friction cereal chamber 60. When opening, the collar 81 is pressed by the rice grains, and the resistance valve 80 is lowered against the urging force applied from the resistance valve link frame 82. As a result, the grain outlet 60A is opened at an opening degree corresponding to the pressing force to the resistance valve 80 by the rice grains in the friction cereal chamber 60. Then, the rice grains that have undergone the friction treatment fall from the grain outlet 60A into the support base 100 and are discharged out of the case 12 from the discharge basket 102 by the rotating discharge disc 98.

  Here, in the friction grain roll 56, the roll part 64 is comprised by the some division part 64A divided | segmented into the axial direction, and the parallel protrusion 56A is attached to the outer periphery of the roll part 64, and several division part 64A. Is connected. Therefore, as in the case of a large-sized friction milling roll 56 for business use, even if the roll part 64 has a long shape in the axial direction, each divided part 64A can be made short in the axial direction. The division part 64A can be easily processed. Thereby, the roll part 64 can be processed easily and cost can be reduced.

  In addition, since the divided portion 64A and the divided portion 64A are connected by the parallel protrusions 56A, a boss or the like (such as the boss portion 66) is provided at the connection portion between the divided portion 64A and the divided portion 64A. It is possible to eliminate the need to prevent vibration between the portion 64A and the divided portion 64A.

  Furthermore, a boss portion 66 for transmitting the driving force of the longitudinally rotating main shaft 22 to the frictional grain roll 56 is provided only at the lower end of the roll portion 64. For this reason, the hollow part in the roll part 64 can be enlarged, and the friction grain roll 56 can be lightened.

  Unlike this embodiment, as shown in FIG. 7, the parallel protrusion 56A may be constituted by a plurality of (two in this embodiment) divided protrusions 78 (divided protrusions) obtained by dividing the parallel protrusion 56A in the longitudinal direction. . In this case, the split ridge 78 straddles the upper split portion 64A and the lower split portion 64A, and the bolt 76 fastening portion of the split ridge 78 includes the upper split portion 64A and the lower split portion 64A. The upper divided portion 64 </ b> A and the lower divided portion 64 </ b> A are connected by the divided protrusion 78.

  Further, in the present embodiment, it has been described that the rice grains are polished by the vertical grinding and friction integrated grain refiner 10. However, grains other than the rice grains (wheat etc.) can also be refined.

It is a front view which shows the vertical grinding friction integrated grain refiner which concerns on one Embodiment of this invention. It is a front sectional view showing the vertical grinding friction integrated grain refiner concerning one embodiment of the present invention. It is a disassembled perspective view which shows the principal part of the vertical grinding friction integrated grain refiner which concerns on one Embodiment of this invention. It is front sectional drawing which shows the principal part of the vertical grinding friction integrated grain refiner which concerns on one Embodiment of this invention. It is a front view which shows the friction grain roll of the vertical grinding friction integral type grain refiner which concerns on one Embodiment of this invention. It is a top view which shows the friction mash roll of the vertical grinding friction integral pulverization apparatus which concerns on one Embodiment of this invention. It is a front view which shows another example of the friction grain roll of the vertical grinding friction integrated grain refiner which concerns on one Embodiment of this invention.

Explanation of symbols

10 Vertical grinding friction integrated grain refiner (friction milling machine)
56 Friction cereal roll 56A Parallel ridge (milling process)
58 Friction milling cylinder 64 Roll part 64A Dividing part

Claims (2)

A roll part constituted by a plurality of divided parts constituting the outer periphery and divided in the axial direction;
A sprouting protrusion that protrudes from the outer periphery of the roll part and is attached to the outer periphery of the roll part to connect the plurality of divided parts;
With
A friction milling roll in which the grains in the friction milling cylinder are frictionally milled by being arranged and rotated inside a cylindrical milling mill. A friction milling tube made into a cylindrical shape,
Friction cereal roll in which the grains in the friction sperm are arranged by rotating inside the friction cereal cylinder and rotated, and
A roll part constituted by a plurality of divided parts divided in the axial direction, which constitutes the outer periphery of the frictional grain roll,
A sprouting protrusion that protrudes from the outer periphery of the roll part and is attached to the outer periphery of the roll part to connect the plurality of divided parts;
Friction milling machine equipped with.

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