JPH02307544A - Flour milling roll machine - Google Patents

Abstract

PURPOSE:To easily detach and mount a roll without removing a roll gap control means by providing the roll gap control means at a position separated from a roll going-in and-out notch opening. CONSTITUTION:Roll going in and out notches 7 are provided to both side walls 6 of a frame 1 corresponding to an opening 4 and a movable bearing 8 is arranged on the closed side of the opening 4 and a fixed bearing 9 is arranged in the vicinity of the opening 4 and a low speed roll 3 is mounted to the movable bearing 8 and a high speed roll 2 is mounted to the fixed bearing 9. The lower end part of the movable bearing 8 is pivotally mounted to the side walls 6 through a roll opening and closing eccentric wheel 10 and the upper end part thereof is connected to a roll fine adjustment eccentric wheel 14 through a coned disc spring 15. When the rolls are replaced, the roll going in and out notches 7 are exposed and the fixed bearing 9 is detached from the mounts of the side walls 6 and the high speed roll 2 is taken out of the machine from the opening 4 along with the fixed bearing 9 while both end shaft parts of the roll 2 are supported and, thereafter, the movable bearing 8 is divided to take out the low speed roll 3 to the outside from the opening 4.

Description

[Detailed description of the invention] [Industrial application field] This invention relates to a flour milling roll machine.

[Conventional technology]

A conventional roll machine will be explained with reference to Fig. 6.7. 6 and 7 show a so-called multiple roll machine, in which one frame is partitioned by a partition, and each frame is provided with a pair of rolls 101 and 102 symmetrically. Usually, a roll 102 for low speed rotation is arranged on the partition side. The roll 101 for high-speed rotation has a fixed bearing 10.
3, the rolls 102 for low speed rotation are each pivotally mounted by movable bearings 104, and the movable bearings 104 are rotatably provided around a fulcrum pin 105 by a roll gap adjustment means.

That is, the shaft of the roll gap adjustment handle 106 provided outside the frame and the connecting rod 10 connected to the moving bearing 104.
7 are connected by an arm 108, and a pin 109 serving as a fulcrum is provided closer to the connecting rod 107 than the center of the arm 108, and by operating the handle 106, the movable bearing 104 is moved far and near from the fixed bearing 103. The gap between the rolls 101 and 102 was adjusted.

By the way, when replacing the rolls 101, 102 due to wear or the like, the left and right side walls 110, 1
The adjustment means at 10 had to be removed, which was cumbersome.

On the other hand, recently, instead of using the handle 106, the roll gap has been adjusted using a motor or the like controlled by a microcomputer.
etc.). However, there has not been much progress in replacing rolls, and even in Japanese Patent Publication No. 60-52862, as a roll gap adjustment means, the connecting rod that connects both bearings is removed, and then both ends of the roll are replaced with a winch or the like. had to be lifted and the roll replaced.

In view of the above-mentioned problems, the technical object of the present invention is to provide a flour milling roll machine in which the rolls can be more easily removed and attached without removing the roll gap adjusting means.

[Means to solve the problem]

In order to achieve the above object, in the flour milling roll machine of the present invention, a fixed bearing is fixed to the opening side and a movable bearing is fixed to the closed side of the roll entry and exit notches provided on the opposing side walls, and the fixed bearing is In a flour milling roll machine comprising at least one horizontally mounted pair of rollers that rotate in opposite directions, with a high-speed roll mounted on a moving bearing and a low-speed roll mounted on a moving bearing, a. It is divided into two parts and one can be attached to and removed from the fixed bearing side.

The other end of the opening is pivotally connected to the side wall via a roll opening/closing eccentric wheel provided with a roll opening/closing eccentric wheel drive means.

C. Engage the other end with the roll fine adjustment shaft.

2. This roll fine adjustment shaft is connected via a disc spring to a roll fine adjustment eccentric wheel having a roll fine adjustment eccentric wheel driving means provided on the side opposite to the fixed shaft of the movable bearing.

This technical measure was taken.

The roll opening/closing eccentric wheel drive means preferably connects an air cylinder to an arm pivotally attached to a bearing of the eccentric wheel.

Furthermore, it is effective that the roll fine adjustment eccentric wheel driving means is one in which a worm driven by a motor is engaged with a worm gear rotatably attached to the main shaft of the eccentric wheel.

[Action and effect]

When replacing the rolls in the flour milling roll machine configured as described above, the fixed bearing is removed from the side wall, and the high-speed roll is taken out of the machine together with the bearing using a winch or the like through the opening of the roll entry/exit notch. Next, with the fixed bearing side of the movable bearing divided, the low speed roll is taken out of the machine through the opening along with the bearing. Then, insert the replacement low-speed roll together with the bearing from the gap L1 and attach it to the moving bearing on the closing side, and combine the divided moving bearings,
Next, a high-speed roll with a fixed bearing is inserted through the opening and fixed to the side wall.

As described above, according to the flour milling roll machine of the present invention, the roll gap adjustment means is provided at a position further away from the opening of the roll entry/exit notch, so that the roll gap adjustment means can be used even when the rolls are taken in and out with a winch or the like. Moreover, this makes it possible to arrange, for example, a control unit in the vicinity of the fixed bearing.

[Embodiments of the invention]

Hereinafter, preferred embodiments of the present invention will be described based on the drawings. Openings 4 are formed in the front and rear walls of the frame 1 forming the roll machine, respectively, for the entry and exit of the high-speed roll 2 and the low-speed roll 3, and a roll cover 5 is removably attached to this opening 4. . Moreover, corresponding to the opening 4, cutouts 7 for rolls in and out are provided on both side walls 6 of the frame 1.

This roll entry/exit notch 7 is wide on the opening 4 side, extends horizontally in a long and narrow manner toward the center, and is closed. Then, a movable bearing 8 is disposed on the closed side of the roll entry/exit notch 7, and a fixed bearing 9 is disposed near the opening 4, and the low-speed roll 3 is disposed on the movable bearing 8, and the high-speed roll 2 is disposed on the fixed bearing 9. wear it. A contact plate 48 is provided between the fixed bearing 9 and the movable bearing 8.

That is, the fixed bearing 9 is fixed to the side wall 6 of the frame 1 with bolts, while the movable bearing 8 has a split case 8a formed in about half of the fixed bearing 9 side, and is removably fixed to the movable bearing 8 with bolts. be done. Furthermore, the moving bearing 8
The lower end is pivotally connected to the side wall 6 via a roll opening/closing eccentric 10, and as a drive means for the eccentric 10, a roll opening/closing air cylinder 13 is attached to an arm 12 pivotally attached to the main shaft 11 of the eccentric 10. It is connected.

The upper end of the movable bearing 8 (see FIGS. 2 to 4) is attached to the roll fine adjustment eccentric wheel 14, which has a roll fine adjustment eccentric wheel drive means provided on the side of the movable bearing 8 opposite to the fixed bearing 9. 1
5.

To explain this in detail, a groove 16 is formed at the upper end of the moving bearing 8, and a roll fine adjustment shaft 17 is disposed within this groove 16.
are horizontally engaged, and furthermore, the roll fine adjustment shaft 17 is loosely fitted into the pair of fixed plates 18 and 19, respectively. A pair of fixed plates 18, 19 are fixed by two screw shafts 20, 20. Then, a thin locking portion 17a formed on the roll fine adjustment shaft 17 and the fixed plate 1 on the fixed bearing 9 side are connected.
A plurality of disc springs 15 are inserted between the locking portion 17a and the fixed plate 19 near the center of the side wall 6, and a moving bearing 9 is inserted between the locking portion 17a and the fixed plate 19 near the center of the side wall 6.
Insert the upper end of the The fixed plate 19 is formed with a convex portion 21.21 at the contact portion with the upper end of the movable bearing 8, and the movable bearing 8 is formed in correspondence with the convex portions 21, 21.
A recess 22.22 is formed at the upper end. In addition, the moving bearing 8
Several rings 23 are interposed between the upper end and the locking portion 17a, and a convex portion 24 is formed at the upper end of the movable bearing 8 that contacts the rings 23.

The eccentric wheel drive means for fine roll adjustment will be explained.

A flange wall 2 formed vertically along the center line of the side wall 6
The gear case 26 is fixed to the bottom and the motor 27 for reversible rotation is fixed to the top.
The worm 28 is attached to the shaft of the worm 28.
A worm wheel 29 that meshes with the worm wheel 29 is built-in. The worm wheel 29 is supported by the main shaft 14a of the roll fine adjustment eccentric wheel 14 attached to the gear case 26, and connects the roll fine adjustment shaft to the eccentric rod 30 of the eccentric wheel 14.

In addition, a cover 34 covers the high speed roll 2 and the low speed roll 3.
The grinding chamber 35 is formed by surrounding the grinding chamber 3.
The lower part of 5 is the outflow hopper 32, and the outflow hopper 32
The lower end of the conveying pipe 33 is exposed inside. A stock supply means is provided above the grinding chamber 35. That is, a stock supply cylinder 36 made of a transparent wall is provided in the center of the upper wall of the frame 1, and the inside of the stock supply cylinder 36 is divided into two by a partition plate 37 in order to supply stock to two pairs of rolls, and a stock supply chamber is formed. 38.38 is formed. Each of the stock supply chambers 38 and 38 has an upper limit level sensor 3.
9 and a lower limit level sensor 40 are provided and connected to a control section (not shown). The lower part of the supply chamber 38 is a supply hopper 41
At the lower end of the supply hopper 41, two feed rolls 42 and 43 driven by a motor (not shown) are provided in parallel. A feeder gate plate 44 is provided along with either of the feed rolls 42 and 43, and the feeder gate plate 44 can be opened/closed and its opening degree adjusted freely by a feeder gate opening/closing cylinder 45 and a feeder gate adjusting device 46. provided. A guide chute 47 is installed upright next to the feed rolls 42 and 43. The lower end of the guide chute 47 faces above the gap between the high speed roll 2 and the low speed roll 3 of the grinding chamber 35.

Next, specific operations in the above embodiment will be explained. When the main motor (not shown) is turned on to rotate the high-speed roll 2 and the low-speed roll 3, the roll opening/closing cylinder 13 is extended by an electric signal from the control section, and the arm 12
As the main shaft 11 rotates (two-dot chain line in FIG. 2), the roll opening/closing eccentric wheel 10 moves the movable bearing 8 largely toward the fixed bearing 9, and primary rough adjustment of the roll gap is performed. At this time, the movable bearing 8 rotates around the convex portion 24 and concave portion 22 at the upper end and the convex portion 21 of the fixed plate 19 as fulcrums. - When the next set adjustment is performed, the motor 27 is started to rotate the roll fine adjustment eccentric wheel 10, and the roll fine adjustment shaft 17 pushes the fixing plate 18 via the disc spring 15. The concave portion at the upper end of the moving bearing 8 receives a pressing force from the convex portion 21 of the fixed plate 19, and the low-speed roll 3 rotates toward the high-speed roll 2 around the roll opening/closing eccentric 10, setting an appropriate gap. be done.

In this way, after the secondary fine adjustment is performed, the stock accumulates in the stock supply chamber 38, and the upper limit level sensor 38
When the feeder gate opening/closing cylinder 45 is driven to open the feeder gate plate 44, the feed rolls 42 and 43 rotate together in the direction of transporting the stock toward the guide chute 47, and the feeder gate opening/closing cylinder 45 is driven to open the feeder gate plate 44. The material is fed into the guide chute 47 at an appropriate speed while being stretched uniformly in the direction. The stock flowing down from the guide chute 47 is subjected to a grinding action by passing through the gap between the high-speed roll 2 and the low-speed roll 3, falls into the outflow hopper 32, and is air-transported to the next process via the conveying pipe 33. be done.

When the stock in the stock supply chamber 38 decreases and the lower limit level sensor 40 detects "no stock", the feeder gate plate 44 closes and the feed roll 42.
43 stops, the motor 27 reverses, and the roll fine adjustment shaft 1
The upper end of the movable bearing 8 is pulled in the roll opening direction by the locking part 17a of the roll opening/closing cylinder 1.
3 and rotate the arm 12 downward to widen the roll gap. In this state, turn off the power and stop the main motor.

The roll exchange will be explained below. When replacing the roll, remove the covers on both sides of the frame 1 (left side of the center line in FIG. 1), remove the roll cover 5, the contact plate 48 of the side wall 6, etc., and expose the roll entry/exit notch 7.

First, remove the fixed bearing 9 from the mount on the side wall 6,
Using a winch or the like, the high-speed roll 2 is taken out of the machine from the opening 40 together with the fixed bearing 9 while supporting both end shaft portions. Next, the movable bearing 8 is divided, and the low-speed roll 3 is taken out from the machine through the opening 4 in the same manner as described above with the bearing attached. The installation of the roll is contrary to the above, after the replacement low-speed roll 3' with the bearing still attached is attached to the movable bearing 8, the divided movable bearing 8a is combined, and the fixed bearing 9 is attached.
Insert the replacement high-speed roll 2 equipped with the roller 2 toward the opening 4 side, fix the fixed bearing 9 to the mount, and attach the covers.

FIG. 5 shows another embodiment of a simpler structure of the roll gap fine adjustment means, in which the roll fine adjustment shaft 17 is engaged with the groove 16 at the upper end of the moving bearing 8, and the upper end is connected to the locking part 17a. It is interposed between the disc spring 15 and the disc spring 15. That is, the plate 49 fixed to the recess on the fixed bearing 9 side of the groove 16 and the fine adjustment shaft 17
and the anti-fixed shaft 9 of the groove 16.
The side convex portion is pressed by one end of the disc spring 15 via the ring 23, and the other end of the disc spring 15 is locked by a nut 50. In this case, the disc spring 15 is directly interposed to move the moving bearing 8 in both the roll closing direction and the roll opening direction. In this case, the vicinity of the fixed bearing 9 can be opened more fully than in the previous embodiment, making it easier to move the roll in and out.

[Brief explanation of drawings]

FIG. 1 is a partially sectional side view showing an embodiment of the present invention, FIG. 2 is a partially enlarged view of FIG. 1, and FIG. 3 is a partially plan view of FIG.
FIG. 4 is a partial perspective view of FIG. 2, FIG. 5 is a partially enlarged sectional view of another embodiment, FIG. 6 is a front view of the conventional example, and FIG. 7 is a partially cutaway view of FIG. 6. FIG. DESCRIPTION OF SYMBOLS 1... Frame, 2... Roll for high speed, 3... Roll for low speed, 4... Opening, 5... Roll cover, 6
... Side wall, 7 ... Notch for roll entry and exit, 8 ... Movable bearing, 8a ... Split case, 9 ... Fixed bearing, 10
...Eccentric wheel for opening and closing rolls, 11...Main shaft, 12...
・Arm, 13... Air cylinder for opening and closing the roll, 1
4... Eccentric wheel for roll fine adjustment, 14a... Main shaft, 1
5... Belleville spring, 16... Groove portion, 17... Roll fine adjustment shaft, 17a... Locking portion, 18.19... Fixing plate, 20... Screw shaft, 21... Convex portion, 22...
recess, 23... ring, 24... recess, 25...
Flange wall, 26... Gear case, 27... Motor, 28... Worm, 29... Worm wheel, 30... Eccentric rod, 31... Scraper, 32...
・Outflow hopper, 33...Low speed pipe, 34...
Cover, 35... Grinding chamber, 36... Stock supply tube, 37... Partition plate, 8... Stock supply chamber, 39
... Upper limit level sensor, 40... Lower limit level sensor, 41... Supply hopper, 42.43... Feed roll, 44... Feeder gate plate, 45...
・Cinder for opening/closing feeder gate, 46... Feeder gate adjustment device, 47... Guide chute, 48.
... Our plate, 49... Plate, 50... Natsuto

Claims (3)

[Claims] (1) A fixed bearing is fixed to the opening side of the roll entry/exit notch provided on each opposing side wall, and a movable bearing is fixed to the closed side, and a high-speed roll is attached to the fixed bearing, and a low-speed roll is attached to the moving bearing. In a flour milling roll machine in which at least one or more pairs of rolls, each of which is mounted on a shaft and rotated at different speeds, are mounted horizontally, each of the movable bearings is divided into two parts, and one of the movable bearings is detachably attached to the fixed bearing side. , the other one end is pivotally connected to the side wall via a roll opening/closing eccentric wheel provided with a roll opening/closing eccentric drive means, and the other end is engaged with a roll fine adjustment shaft, thereby finely adjusting the roll. 1. A flour milling roll machine, wherein the shaft is connected via a disc spring to an eccentric wheel for fine roll adjustment having a drive means for an eccentric wheel for fine roll adjustment provided on the opposite side of the fixed shaft of the movable bearing. (2) The flour milling roll machine according to claim 1, wherein the roll opening/closing eccentric wheel driving means is formed by connecting an air cylinder to an arm pivotally attached to the main shaft of the eccentric wheel. (3) Flour milling according to (1) or (2), wherein the roll fine adjustment eccentric wheel drive means is formed by meshing a worm operated by a motor with a worm gear rotatably attached to the main shaft of the eccentric wheel. roll machine.