JP7277122B2 - screen basket - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to screen baskets, and more particularly to screen baskets having perforated plates for separating foreign matter from papermaking stock.

Conventionally, there has been known a screen device for sorting papermaking raw materials into accepts, which are high-quality fibers, and rejects, which are foreign substances such as plastics and sand. Such screen devices have a screen basket and an agitating member. The stirring member rotates within the screen basket to generate a vortex in the papermaking material. The screen basket has a perforated plate. The multi-hole plate is provided with a large number of fine holes so that accepts can pass through but rejects cannot pass through. In this way, the swirling papermaking raw material is sorted into accepts and rejects by a screen basket (see Patent Document 1). The perforated plate is arranged around the entire cylindrical circumference of the screen basket, as shown in Figure 3 of D1. At this time, the porous plate is provided with a large number of fine holes, but is free from irregularities.

Japanese Patent Application Laid-Open No. 2017-101353

At present, there is a further demand for the development of screen baskets capable of more efficiently sorting raw materials for papermaking. However, in order to increase the diameter and height of the screen basket in order to increase the area of the perforated plate, the size of the screen device itself had to be increased.

Accordingly, the present invention has been made in view of the above problems, and an object of the present invention is to provide a technique capable of more efficiently sorting papermaking raw materials while suppressing the size of the screen basket.

In order to solve the above-mentioned problems, the screen basket according to the present invention has a perforated plate for separating foreign matters from the papermaking raw material, and the perforated plate is formed in a corrugated shape that undulates in the flow direction of the papermaking raw material. According to this aspect, the area of the porous plate can be increased while maintaining the size thereof. Therefore, the papermaking raw material can be sorted more efficiently while suppressing the size of the screen basket.

When the perforated plate is traced in the direction of flow of the papermaking raw material, the corrugation has a first inclined portion inclined toward the inside of the screen basket and a second inclined portion inclined toward the outside of the screen basket with respect to the direction of flow of the papermaking raw material. 2 ramps. The first inclined portion may be inclined more gently with respect to the flow direction of the papermaking raw material than the second inclined portion. As a result of diligent research and development by the inventor, by providing the first inclined portion and the second inclined portion in this manner, turbulence is generated when the raw material for papermaking flows from the first inclined portion along the second inclined portion. 2 was found to be formed around the slope. This turbulent flow can prevent the solids from entering and clogging the micropores of the multi-aperture plate. Therefore, according to this aspect, the sorting effect of the micropores can be maintained even after long-term use.

The second inclined portion may be inclined perpendicularly to the flow direction of the papermaking raw material. According to this aspect, turbulence can be formed more effectively.

A plurality of perforated plates having the same shape may be provided, and the plurality of perforated plates may be stacked perpendicularly to the flow direction of the papermaking raw material. According to this aspect, since the height of the screen basket can be changed by increasing or decreasing the number of stacked perforated plates, the capacity of the screen basket can be easily changed using the perforated plates of the same shape. can be done. Therefore, the perforated plate can be commonly used in screen baskets of various sizes, and the cost of the screen basket can be suppressed.

A reinforcing plate for fixing the plurality of porous plates between the laminated plurality of porous plates may be further provided. The reinforcing plate may have grooves along the flow direction of the papermaking raw material on the surface to which the plurality of perforated plates are to be fixed. The plurality of perforated plates may be fixed to the reinforcing plate by inserting their ends into the grooves and brazing. Due to the large number of fine holes provided, the perforated plate is relatively thin and it is difficult to fix the perforated plate to the reinforcing plate by welding. According to this aspect, the relatively thin and wavy perforated plate can be appropriately fixed to the reinforcing plate.

It has a plurality of perforated plates of the same shape, and the plurality of perforated plates are arranged along a circle while being bent in an arc so that the plurality of perforated plates form one circle along the flow direction of the papermaking raw material. may be According to this aspect, since the diameter of the screen basket can be changed by increasing or decreasing the number of perforated plates forming one circle, the capacity of the screen basket can be easily changed using perforated plates of the same shape. can be made Therefore, the perforated plate can be commonly used in screen baskets of various sizes, and the cost of the screen basket can be suppressed.

A plurality of reinforcing rods extending perpendicularly to the direction of flow of the papermaking stock may further be provided to secure the plurality of perforated plates between the plurality of perforated plates. The plurality of reinforcing rods may each have a groove extending perpendicularly to the flow direction of the papermaking raw material on the surface to which the plurality of perforated plates are to be fixed. The plurality of perforated plates may be fixed to the reinforcing rods by inserting their ends into the grooves and brazing. According to this aspect, a relatively thin perforated plate can be properly fixed to the reinforcing rod.

(a) is a front view of the screen basket according to the first embodiment, and (b) is a top view of the screen basket according to the first embodiment. (a) is a cross-sectional view taken along line AA of FIG. 1(a), and (b) is an enlarged view of region B of (a). (a) is a front view of a multi-aperture plate, (b) is a top view of the multi-aperture plate, and (c) is an enlarged view of region C of (b). (a) is a view of FIG. 2(a) with the perforated plate removed, and (b) is an enlarged view of region D of (a). (a) is a front view of a screen basket according to a second embodiment, and (b) is a cross-sectional view taken along line EE of (a).

(First embodiment)
FIG. 1(a) is a front view of the screen basket 10 according to the first embodiment, and FIG. 1(b) is a top view of the screen basket 10 according to the first embodiment. The screen basket 10 is formed in a cylindrical shape with a bottom. A stirring member (not shown) is housed inside the screen basket 10 , and the rotation of the stirring member generates a swirl in the papermaking material inside the screen basket 10 . In the first embodiment, the flow direction F of the papermaking raw material (hereinafter simply referred to as "flow direction F") is clockwise when viewed from above, as shown in FIG. 1(b). However, the flow direction F may be counterclockwise when viewed from above.

The screen basket 10 has one top plate 12 , one bottom plate 14 , a plurality of reinforcing plates 16 , a plurality of reinforcing rods 18 and a plurality of perforated plates 20 . The top plate 12 is formed in an annular shape from metal such as stainless steel. The bottom plate 14 is formed in a disc shape from metal such as stainless steel.

A plurality of perforated plates 20 are arranged around the screen basket 10 . A plurality of porous plates 20 are formed in the same shape. The multi-hole plate 20 is provided with a large number of fine holes so that accepts can pass through but rejects cannot pass through. A layer composed of a plurality of perforated plates 20 is laminated perpendicularly to the flow direction F on the peripheral surface of the screen basket 10 . In a first embodiment, eight layers of perforated plates 20 are stacked perpendicular to the flow direction F. FIG. However, it goes without saying that the number of stacked porous plates 20 is not limited to eight.

Since the height of the screen basket 10 can be changed by increasing or decreasing the number of stacked perforated plates 20, the capacity of the screen basket 10 can be easily changed using the perforated plates 20 of the same shape. . Therefore, the multi-hole plate 20 can be commonly used in the screen baskets 10 of various sizes, and the cost of the screen basket 10 can be suppressed.

The reinforcement plate 16 fixes the plurality of porous plates 20 between the plurality of laminated porous plates 20 . The reinforcing plate 16 is formed in an annular shape from metal such as stainless steel. First, the lower ends of the plurality of porous plates 20 are fixed to the upper surface 14a of the bottom plate 14 along the outer periphery. Next, the lower surface 16b of the reinforcing plate 16 is fixed to the upper end portions of the plurality of porous plates 20. As shown in FIG. Next, the lower end portions of another plurality of porous plates 20 are fixed to the upper surface 16 a of the reinforcing plate 16 . By repeating this, the perforated plates 20 can be stacked in the direction perpendicular to the flow direction F.

Between the top plate 12 and the bottom plate 14, a plurality of reinforcing rods 18 are arranged extending perpendicular to the flow direction F. As shown in FIG. The reinforcing rod 18 is formed linearly from metal such as stainless steel. Each of the plurality of reinforcing rods 18 fixes the plurality of perforated plates 20 between the plurality of perforated plates 20 in the flow direction F in each layer.

FIG. 2(a) is a cross-sectional view taken along the line AA of FIG. 1(a). In each layer of the perforated plates 20, a plurality of perforated plates 20 having the same shape are arranged along the circle while being bent in an arc so as to form one circle along the flow direction F. In a first embodiment, six perforated plates 20 are arranged to form a circle in each layer. However, it goes without saying that the number of perforated plates 20 forming a circle is not limited to six.

By increasing or decreasing the number of perforated plates 20 forming one circle, the diameter of the screen basket 10 can be changed. can be done. Therefore, the multi-hole plate 20 can be commonly used in the screen baskets 10 of various sizes, and the cost of the screen basket 10 can be suppressed.

Between the six perforated plates 20 in flow direction F, reinforcing rods 18 are arranged. Each of the six perforated plates 20 is fixed at its end to the side 18a of the reinforcing rod 18. As shown in FIG.

FIG. 2(b) is an enlarged view of region B in FIG. 2(a). Currently, there is a demand for more efficient sorting of papermaking raw materials while reducing the size of screen baskets. For this reason, the perforated plate 20 according to the first embodiment is formed into a wave that undulates in the flow direction F. As shown in FIG. As a result, the area of the porous plate 20 can be increased while maintaining the size thereof. Therefore, the papermaking raw material can be sorted more efficiently while suppressing the size of the screen basket 10 .

In addition, when the porous plate is flat, the rigidity of the porous plate is lower than when the plate is corrugated. Therefore, it is necessary to arrange more reinforcing plates and reinforcing rods or to form them thicker. However, the reinforcing plates and reinforcing rods are not provided with fine holes. Therefore, when the perforated plate is a flat plate, the ratio of the area of the reinforcing plate and the reinforcing rod to the area of the peripheral surface of the screen basket is high, and the area of the region in which the fine holes are provided with respect to the area of the peripheral surface of the screen basket. lower percentage. According to the first embodiment, the rigidity of the multi-hole plate 20 can be increased by forming the multi-hole plate 20 into a corrugated shape. Therefore, the number and thickness of the reinforcing plates 16 and the reinforcing rods 18 can be reduced, and the ratio of the area of the region provided with the fine holes to the area of the peripheral surface of the screen basket 10 can be increased. Therefore, the opening ratio of the fine holes to the peripheral surface of the screen basket 10 can be increased.

The corrugation of the multi-aperture plate 20 has a first sloped portion 20a and a second sloped portion 20b. The first inclined portion 20a is inclined toward the inside of the screen basket 10 with respect to the flow direction F when the perforated plate 20 is followed in the flow direction F. The second inclined portion 20b is inclined toward the outside of the screen basket 10 with respect to the flow direction F when the perforated plate 20 is traced in the flow direction F.

In the first embodiment, the first sloped portion 20a slopes more gently with respect to the flow direction F than the second sloped portion 20b. As a result of diligent research and development by the inventor, by providing the first inclined portion and the second inclined portion in this way, the turbulent flow G can be generated when the raw material for papermaking flows from the first inclined portion along the second inclined portion. It has been found that it can be formed around the second inclined portion. This turbulent flow G can prevent solids from entering and clogging the micropores of the multi-hole plate, and the separation effect of the micropores can be maintained even in long-term use. In addition, the second inclined portion 20b is inclined substantially perpendicularly to the flow direction F. As shown in FIG. Thereby, the turbulent flow G can be formed more effectively.

FIG. 3(a) is a front view of a multi-aperture plate. In the first embodiment, the perforated plate 20 is shaped like a rectangle elongated in the flow direction F. As shown in FIG. The perforated plate 20 has corrugations 20c and side edges 20d. A wave that undulates in the flow direction F is formed in the wave portion 20c. The side edge 20d is the edge of the perforated plate 20 in the flow direction F. The side end portion 20d is formed in a flat plate shape and is not formed in a corrugated shape.

The perforated plate 20 is formed by pressing a flat plate-shaped punching metal into a corrugated shape using a die. The corrugation is consistently formed between the upper end 20e and the lower end 20f so that the corrugation can be easily formed by press molding. Therefore, the upper end portion 20e and the lower end portion 20f of the multi-hole plate 20 are not flat like the side end portions 20d. The porous plate 20 is provided with a large number of fine holes with a diameter of 0.07 at a pitch of 0.3 mm.

FIG. 3(b) is a top view of the multi-aperture plate. When the multi-hole plate 20 is not attached to the screen basket 10, the perforated plate 20 does not have an arc shape when viewed from above, but has a straight shape.

FIG.3(c) is an enlarged view of the area|region C of (b). In the first embodiment, the thickness t of the porous plate 20 is 0.4 mm, the corrugation interval L is 5 mm, and the corrugation height H is 2 mm. Between the first inclined portion 20a and the second inclined portion 20b, a first curved portion R1 is provided on the radially outer side of the screen basket 10, and a second curved portion R2 is provided on the radially inner side thereof. The inner diameters of the first curved portion R1 and the second curved portion R2 are each 0.5 mm. It goes without saying that the perforated plate 20 is not limited to these dimensions.

FIG. 4(a) is a diagram of FIG. 2(a) with the multi-hole plate 20 removed. The reinforcement plate 16 has grooves 16c of the same shape along the flow direction F on the upper surface 16a and the lower surface 16b, which are the surfaces to which the plurality of porous plates 20 are to be fixed. The porous plate 20 is fixed to the reinforcing plate 16 by inserting the lower end portion into the groove 16c of the upper surface 16a of the reinforcing plate 16 and brazing. The porous plate 20 is fixed to the reinforcing plate 16 by inserting the upper end portion into the groove 16c of the lower surface 16b of the reinforcing plate 16 and brazing.

Further, the upper surface 14a of the bottom plate 14 is also formed with grooves (not shown) having the same shape. The multi-aperture plate 20 is fixed to the bottom plate 14 by inserting its lower end into a groove in the upper surface 14a of the bottom plate 14 and brazing. The bottom surface 12a of the top plate 12 is also formed with grooves (not shown) having the same shape. The perforated plate 20 is fixed to the top plate 12 by inserting the lower end portion into a groove of the lower surface 12a of the top plate 12 and brazing.

Since the multi-hole plate 20 is provided with a large number of fine holes, the multi-hole plate 20 is relatively thin. Therefore, it is difficult to fix the perforated plate 20 to the reinforcing plate 16 and the reinforcing rods 18 by welding. Through the use of grooves and brazing, the relatively thin and corrugated perforated plate 20 can be adequately secured to the top plate 12, bottom plate 14, and stiffener plate 16. FIG.

In the first embodiment, jig metal 70° C. (manufactured by Machinesol Co., Ltd.) is used for brazing. However, it goes without saying that other brazing materials may be used.

FIG. 4(b) is an enlarged view of region D in FIG. 4(a). A plurality of reinforcing rods 18 each have a groove 18c extending perpendicularly to the flow direction F in the surface to which the plurality of perforated plates 20 are to be fixed. Each of the plurality of perforated plates 20 is fixed to the reinforcing rod 18 by inserting the side end 20d into the groove 18c and brazing. A relatively thin perforated plate 20 can be adequately secured to the reinforcing rods 18 by using grooves and brazing.

(Second embodiment)
FIG. 5(a) is a front view of a screen basket 50 according to a second embodiment, and FIG. 5(b) is a cross-sectional view taken along line EE of FIG. 5(a). Configurations similar to those of the first embodiment are denoted by the same reference numerals, and descriptions thereof are omitted.

The screen basket 50 has a top plate 52 , a bottom plate 54 , a reinforcing plate 56 , reinforcing rods 15 and a perforated plate 20 . Top plate 52, bottom plate 54, and reinforcement plate 56 are similar to top plate 12, bottom plate 14, and reinforcement plate 16 of the first embodiment, except that they have a larger outer diameter. Reinforcement rods 58 are similar to reinforcement rods 18 of the first embodiment except that they are longer in length.

In a second embodiment, eleven layers of perforated plates 20 are stacked perpendicular to the flow direction F. FIG. The same multi-aperture plate 20 as in the first embodiment can also be used in the second embodiment. In this way, the capacity of the screen basket 10 can be easily changed by increasing or decreasing the number of stacked perforated plates 20 and by increasing or decreasing the number of perforated plates 20 forming a circle in each layer.

10 screen basket, 12 top plate, 12a lower surface, 14 bottom plate, 14a upper surface, 16 reinforcing plate, 16a upper surface, 16b lower surface, 16c groove, 18 reinforcing rod, 18a side surface, 18b groove, 20 perforated plate, 20a first inclined portion , 20b second inclined portion 20c waveform portion 20d side end portion 20e upper end portion 20f lower end portion

Claims (6)

Having a perforated plate for separating foreign matter from the papermaking raw material,
The perforated plate is formed in a corrugated shape that undulates in the flow direction of the papermaking raw material ,
Having a plurality of said porous plates of the same shape,
The plurality of perforated plates are arranged along the circle while being bent in an arc so that the plurality of perforated plates form a circle along the flow direction of the papermaking raw material,
further comprising a plurality of reinforcing rods extending perpendicular to the flow direction of the papermaking raw material, fixing the plurality of perforated plates between the plurality of perforated plates;
The plurality of reinforcing rods each have grooves extending perpendicular to the flow direction of the papermaking raw material on the surface to which the plurality of porous plates are to be fixed,
The screen basket , wherein the ends of the plurality of perforated plates are inserted into the grooves and fixed to the reinforcing rods . The corrugations are formed on the outside of the screen basket and a first inclined portion that is inclined toward the inside of the screen basket with respect to the flow direction of the papermaking raw material when the perforated plate is traced in the flow direction of the papermaking raw material. and a second inclined portion inclined in the direction of
2. The screen basket according to claim 1, wherein said first inclined portion is inclined more gently than said second inclined portion with respect to the flow direction of said papermaking raw material. 3. The screen basket according to claim 2, wherein the second inclined portion is inclined perpendicularly to the flow direction of the papermaking raw material. Having a plurality of said porous plates of the same shape,
4. The screen basket according to any one of claims 1 to 3, wherein said plurality of perforated plates are stacked perpendicularly to the flow direction of said papermaking raw material. further comprising a reinforcing plate for fixing the plurality of porous plates between the plurality of stacked porous plates;
The reinforcing plate has grooves along the flow direction of the papermaking raw material on the surface to which the plurality of perforated plates are to be fixed,
5. The screen basket according to claim 4, wherein the plurality of perforated plates are fixed to the reinforcing plate by inserting their ends into the grooves and brazing. 6. A plurality of perforated plates according to any one of claims 1 to 5, characterized in that the plurality of perforated plates are fixed to the reinforcing rods by inserting their ends into the grooves and brazing them. screen basket.

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