JPH0696834B2 - Undigested material separation device - Google Patents

Abstract

The invention relates to a method and apparatus for separating knots. In particular the method and the apparatus are meant to be used in separating knots from fibre suspensions of the wood processing industry. The knotter according to the invention uses a profiled screen cylinder (5) with which it has been found from performed tests to be most preferable to feed the pulp from the connections (2) in the direction of rotation of the screen cylinder and also to discharge the reject from the connections (4) and the accept from the connections (3) of the cylinder (5) in the direction of rotation. As a result, there is not only less wear of the screen surface, but also a significantly smaller consumption of power per pulp ton than in the apparatuses in accordance with the prior art.

Description

TECHNICAL FIELD OF THE INVENTION The present invention relates to a device for separating undigested material, especially from highly concentrated fiber suspensions.

Background Art and Problems to be Solved by the Invention A plurality of different undigested matter separating apparatuses are known. One of them, U.S. Pat.No. 3,943,314, discloses a device having a cylindrical outer casing and an inner screen casing, a rotary screw coveer located inside the inner screen casing, and an inner screen casing. At the lower end of the outer casing, at the lower end of the outer casing at the accept (pulp material free from foreign matter) outlet, and at the upper end of the inner screen casing in the reject (discard of undigested materials, etc.) Things) exits. The entire device is preferably slightly tilted with respect to the vertical. In the device, undigested material (Kno:
Pulp, including ts) and other fairly large pieces of wood, is fed to the lower end of the inner screen casing and then lifted with a screw complier. As the pulp is lifted by the screw conveyor, fine fibers pass through the holes or slots in the perforated screen and exit through the accept outlet at the lower end of the outer casing. Large material that is not filtered through the holes in the inner screen casing is carried to the upper end of the inner screen casing and dropped from there to the reject chute.

One other prior art device is disclosed in Swedish Patent No. 316363, in which a rotating cylinder of a slightly conical, downwardly flared shape is located inside a cylindrical casing. The screen is listed. A stationary pulsation device is provided inside the cylindrical screen to keep the opening of the cylindrical screen open. Pulp is supplied in the connecting direction to an annular groove provided at the upper end of the outer casing. The pulp flows in the groove along a horizontal plate arranged on the outer casing spiraling towards the axis of the cylindrical screen. The pulp falls through a hole in the center of the horizontal plate onto the end cover of a rotating cylindrical screen. The end cover has radial ribs that give the pulp an initial rolling motion. The pulp is centrifugally thrown from the end cover into a downwardly directed narrow space between the cylindrical screen and the outer casing. The fine fibers migrate to the accept side through the cylindrical screen.
Material left between the outer casing and the cylindrical screen,
That is, the rejects are finally discharged into the annular groove at the lower end of the outer casing and from there towards the connection direction outlet.

Third, the device disclosed in U.S. Pat. No. 4441999 consists of a cylindrical outer casing and a rotating cylindrical screen. Inside the cylindrical screen there is one or more stationary non-rotating blades. Pulp is
It is supplied in a connecting direction between the cylindrical screen and the outer casing, the supplying direction being opposite to the rotating direction of the cylindrical screen. The accept is ejected from the inside of the cylindrical screen at the end of the cylindrical screen, and the reject is ejected in the connecting direction, but in the direction opposite to the rotating direction of the cylinder. In this device configuration, the cylindrical screen consists of an opening that opens towards the inside of the cylinder, and a connecting piece, which in principle comprises a radial arm and a part curved in the direction of pulp flow towards the cylinder. The radial arm and the part further generate a pressure pulse on the pulp, keeping the holes in the cylindrical screen open. The device disclosed in U.S. Pat.
It works particularly well in short circulation of a papermaking machine and enables damping of pressure waves that are harmful to the next process.

The latter two devices achieve a density range of 4 to 6%, and the device of the first example only works at a maximum density of 1.5 to 2%, the clogging of the holes in the cylindrical screen causes its activation in all devices. To limit. However, the goal in raw material processing is consistently towards higher concentrations. Because in any case, without increasing the concentration or diluting,
This is because it is preferable to adjust the pulp to the same consistency in different steps. If the treatment concentration can be increased, the cost can be reduced from the viewpoint of both equipment cost and transfer cost, and also from the aspect of energy consumption.

Means for Achieving the Object The undigested matter separating apparatus according to the present invention has been developed under the above technical background, and enhances the operation efficiency of the separating apparatus, and further, the undigested material in the treated fiber suspension. The purpose is to reduce the effect of impact forces on digests and other solids, thus improving the quality of the treated fiber suspension (pulp).

This object is achieved by providing the following undigested material separator.

An outer housing having an inlet connector for treated fiber suspension, an outlet connector for accepting, and an outlet connector for rejecting, wherein each connector is tangentially attached to the outer housing. A fiber comprising an outer housing, a perforated cylinder supported by a shaft and rotatably disposed within the outer housing, and one or more stationary blades disposed inside the perforated cylinder. A device for separating undigested matter and other solid substances from a suspension, in which a perforated cylinder is rotated in the same direction as the pulp feed direction performed through an inlet connector and through an outlet connector. The reject discharge direction is the same as the rotation direction of the perforated cylinder, and the inlet connector has an outer side so as to supply the treated fiber suspension between the outer housing and the perforated cylinder. It is attached to the Ujingu,
Furthermore, the porous cylindrical body has a plurality of ridges having inclined surfaces and parallel to each other on its outer surface, and the ridges extend in an inclined direction with respect to the rotation axis direction of the porous cylinder, It has an inclination angle within the range of minus (-) 45 ° to plus (+) 45 ° with respect to a straight line parallel to the rotation axis on the outer surface, and when the porous cylinder rotates, the inclined surface suspends fibers. An undigested material separating device configured to act so as to hit the liquid and throw the fiber suspension outward.

In the above description, the fact that the ridges extend at least parallel to the rotation axis of the porous cylinder means that a plurality of ridges are arranged parallel to the rotation axis, or that the ridges are parallel to the rotation axis. It means that they are arranged so as to be inclined with respect to a plurality of virtual reference straight lines on the surface of the cylindrical body.

The greatest feature of the device of the present invention is that the perforated cylinder is rotated in the same direction as the pulp supply direction performed through the inlet connection body, and the reject is discharged through the outlet connection body in the same direction as the rotation direction of the perforated cylinder body. That is the point.

Another feature of the device of the present invention is that the perforated cylinder has a plurality of ridges having inclined surfaces on its outer surface, and the ridges extend at least parallel to the axis of rotation of the perforated cylinder. That is the point. According to this structure, when the porous cylinder rotates, the inclined surface acts on the fiber suspension so as to throw the fiber suspension outward.

According to the device of the present invention, since the supply direction of the fiber suspension to be treated to the undigested material separating device is the same as the rotation direction of the porous cylindrical body, the destruction of the fiber due to the contact with the porous cylindrical body is effectively prevented. (That is, the contact impact between the porous cylinder and the fiber is small). For the same reason, the perforated cylinder does not destroy undigested matter (knots) and other solid particles that would cause trouble in later screening steps. It should be noted here that particles such as undigested matter must be completely removed and must not be finely broken. When the disrupted particles move to a later processing stage, they simply pass through a later screening stage. Particles such as undigested material are not efficiently bleached, resulting in a loss of gloss in the final product.

Further, according to the device of the present invention, the so-called low MC concentration range (6 to 8)
%) Is achieved and energy consumption is significantly reduced. Increasing the applicable concentration range is due to the correct sizing and shape setting of the porous cylinder (screen),
It is achieved by optimizing the rotational speed of the perforated cylinder in relation to the feed rate of the fiber suspension. Further, it has become possible to reduce the energy consumption of the undigested matter separating apparatus itself, mainly as compared with the apparatus of US Pat. No. 4441999. This is mainly due to changing the rotation direction of the porous cylindrical body in the same direction as the pulp supply direction. According to the tests carried out, the energy consumption of the undigested material separator according to the invention itself was a maximum of 0.6 Kwh / ton of fiber (absolute fiber amount: 1 ton; that is, per ton fiber amount in the dry state). Furthermore, changing the direction of rotation also reduced wear of the perforated cylinder.

Another advantage of the device of the present invention is that it is easier to eject rejects as compared to the device described in US Pat. No. 4441999. This is because according to the device of the present invention, rejects are discharged in the rotating direction of the porous cylindrical body (pumping effect). This pumping effect, with the dilution water added to the rejects during the drainage phase, makes it much easier to accommodate large amounts of rejects. Thus, by using the porous cylinder according to the present invention, the rejection rate can be kept at 2 to 10% even at a high concentration.

Example FIG. 1 and FIG. 2 (plan view of the main part of the apparatus shown in FIG. 1 with a cutaway),
In the undigested material separating apparatus shown in FIG. 3 (a vertical sectional view similar to FIG. 1, but only a main part is shown), the pulp (fiber suspension) inlet connection body 2 is Cylindrical outer housing 1 disposed inside and outlet connection body 3 for accept
An outlet connection body 4 for the outer housing, a perforated cylindrical body (cylindrical screen) 5, and one or more stationary blades (non-rotating blades) 6. The stationary blade 6 is provided on the inner surface of the perforated cylindrical body 5. It extends to a close position. The porous cylindrical body 5 is mounted by a member 12 on a shaft 7 driven by, for example, a belt type driving body (not shown). The space 8 between the porous cylinder 5 and the outer housing 1 is annular and is sealed at both ends by radial plates 9, 10 projecting from the outer housing 1 towards the axis. The connectors 2 and 4 are tangentially attached to the outer housing 1 so as to communicate with the annular space 8.

Further, a diluting water supply pipe 11 is attached to the reject outlet connection body 4, and if necessary, the dilution water supply pipe 11 is used to lower the concentration of the reject and facilitate the next screening operation.

The stationary blade 6 is attached to a fixed frame 15 together with the arms 13 and 14, and this fixed frame also forms a column for the shaft 7 via a bearing 16. One of the stationary blades 6 is arranged in the porous cylindrical body 5 near the reject outlet connecting body 4, and the porous cylindrical body 5 of the porous cylindrical body 5 is defined with reference to the connection center of the reject outlet connecting body 4 to the outer housing 1. It is located within an angle range of minus (-) 10 ° to plus (+) 45 ° along the circumferential direction. This arrangement relationship will be described with reference to FIG. FIG. 4 is a cross-sectional view similar to FIG. 2, but FIG. 2 is shown as a cross-sectional view of the main part in a state in which it is looked down from above, while FIG. 4 is looked up from below. It is shown as a schematic cross-sectional view of the state, and is a diagram mainly showing the flow direction of the liquid to be treated (indicated by reference numeral L) and the positional relationship (the above-mentioned angular position relationship) of the stationary blade 6. According to FIG. 4, the center line of the outlet connector 4 intersects with the outer housing 1 at the point P ₄ , and the line segment OP ₄ is used as the circumferential angle reference position (angle = 0) of the porous cylindrical body 5. ), And the flow direction L of the liquid to be treated is the plus (+) direction, and the opposite direction (clockwise direction in FIG. 4) is the minus (-) direction. In this case, stationary blades 6, the line segment OC (point C lies on the circumference showing a porous cylindrical body 5) minus the angular position indicated by (-) line OD (point D from 10 DEG perforated cylinder It is located within an angular range of up to plus (+) 45 °, which is the angular position indicated by (on the circle indicating the body 5).

The other stationary blade 6 is arranged near the pulp inlet connector 2 and is a minus (-) along the circumferential direction of the porous cylindrical body 5 based on the connection center of the inlet connector 2 to the outer housing 1. ) Positioned within an angle range of 10 ° to plus (+) 45 °. This positional relationship will be described with reference to FIG. 4 similarly to the stationary blade 6 near the outlet connector 4 described above. According to FIG. 4, the center line of the inlet connector 2 is the point P ₂
And intersects the outer housing 1 at the line segment OP ₂ as the circumferential angle reference position (angle = 0) of the porous cylindrical body 5,
The flow direction L of the object to be processed is defined as a plus (+) direction, and the opposite direction is defined as a minus (-) direction. At this time, the other stationary blade 6 moves from the line segment OB (point B is indicated by the line segment OA (point A is on the circumference showing the perforated cylindrical body 5) to the line segment OB (point B is indicated by the line segment OA ). (It is on the circumference showing the porous cylindrical body 5)
Positioned within the angular range of plus (+) 45 °, which is the angular position indicated by.

Thus, each stationary blade 6 has a rotating perforated cylindrical body 5
Generate a positive or negative pressure pulse appropriate for the.

FIG. 6 shows the screen (perforated plate forming the wall portion of the perforated cylinder) according to one embodiment in an expanded state. FIG. 5 is a fragmentary sectional view cut along the line AA in FIG. The perforated plate 20 has a flat body portion 22 in which a large number of openings 21 are formed, and a raised portion formed in the body portion 22 between the openings 21. The perforated plate 20 is flat on the inner surface 23 that does not include the openings 21. The outer surface of the perforated plate 20 has a front surface 25 that is raised from the flat surface 24 of the main body portion 22 at a predetermined angle.
A surface 26 substantially parallel to the plane 24 of the body portion 22, a rear surface 27 substantially upright on the plane 24 of the body portion 22, and a plane between the openings 21.
It consists of 24 parts 28 and. On the other hand, the perforated plate 20 can be considered to be composed of a plate having a plurality of ridges 29, which are formed by the front surface 25, the surface 26, the rear surface 27 and the planar portion 28 therebetween. Made, the apertures 21 are formed by machining.

As can be seen in FIG. 6, the apertures 21 are preferably holes (or slots), which in this embodiment have a diameter of at least 5-15 mm. Furthermore, as can be seen from FIG. 6, the ridges 29 may be slightly inclined from the axial direction of the porous cylindrical body 5. Due to the inclination angle of the ridges 29, the inclination direction with respect to the direction of rotation, the rotation speed and the elevation angle of the front face 25 of the ridges 29, the pulp circulation speed of the undigested separator can be optimized with respect to the separation result. In the tests carried out, the peripheral speed of the cylinders used was 4-10 m / sec, at which time the pulp feed rate was 2 m / sec. In this case, the speed difference between the porous cylindrical body 5 and the pulp is 2 to 8 m / sec. The inclined front surface 25 of the ridge 29 receives the pulp entering the porous cylindrical body 5, and the porous cylindrical body 5 is accelerated. When the direction of the ridges 29 is inclined to the rear of the ridges 29 on the porous cylindrical body 5, the ridges 29 act so as to lift the pulp upward, and thus the pulp circulation in the undigested matter separating apparatus. Longer times, more accurate separations, reduced rejects and increased accepts.

The forward inclination in the direction of inclination of the ridge 29 means that when the porous cylinder 5 is viewed from the front, the ridge 29 is a virtual straight line parallel to the rotation axis of the porous cylinder 5 on the cylindrical surface.
Means a state in which the upper end is inclined so as to be biased toward the rotational direction side with respect to the lower end, and the backward inclination means a state inclined in the opposite direction.

When the ridges 29 are inclined rearward, the ridges 29 act as if they lift the pulp upward as the porous cylindrical body 5 rotates, and the pulp circulation time in the apparatus is relatively long. Therefore, the screening efficiency of pulp by the porous cylindrical body 5 is improved, the reject amount is decreased, and the accept amount is increased. Further, when the ridge 29 is inclined forward, the pulp circulation time in the device is shortened,
Although the screening efficiency is relatively reduced as compared with the case of the rearward inclination, there is an advantage that the liquid processing efficiency as a whole is improved. Furthermore, in addition to the above factors, the height of the porous cylindrical body 5 affects the application speed, the inclination angle, and the like.

The device of the present invention functions as follows. The pulp (fiber suspension to be treated) is pressurized and supplied to the space 8 between the porous cylindrical body 5 and the outer housing 1 from the connecting direction, and at that time, the supply is in the same direction as the rotating operation of the porous cylindrical body 5. Has become. Due to its shape, the raised ridges 29 of the porous cylindrical body 5 receive the circumferential direction from the supplied pulp, and the rotation speed of the porous cylindrical body 5 increases. Further, the ridges 29 of the porous cylindrical body 5 give the feed pulp a shearing force for breaking the bond between pulp particles, that is, fibers. The ridges 29 give rise to a low-pressure region at the front outlet end of the rear face 27, which pressure region results in a pressure between the pulp (fiber suspension) inlet connection 2 and the accept outlet connection 3. With the help of the difference, loose fibers (fibers in a loose state, not in a tangled state) are sucked through the openings 21. When the heavy particles carried by the pulp hit the ridges 29, they are thrown towards the inner surface of the outer housing 1 and are also subjected to centrifugal forces. In that case, the light particles of pulp become concentrated near the porous cylinder 5 and are screened from the pulp liquid introduced into the space 8 by the method described above.
Further, in the conventional apparatus, a fibrous film layer (usually containing foreign matter such as undigested matter) is formed on the outer surface of the rotating screen cylinder. Since the ridges 29 having a peculiar shape are formed, when the porous cylinder 5 rotates, turbulences are created by the ridges 29 near the surface of the porous cylinder 5, and the turbulence destroys the fiber membrane layer. Or the formation of a fiber membrane layer is prevented and the separation is assisted while the energy consumption at the time of separation is reduced and the wear of the porous cylindrical body 5 is reduced. The heavy particles separated on the surface of the outer housing 1 move downward while spiraling along the inner surface of the outer housing 1 and are tangentially discharged from the undigested matter separating device through the reject outlet connector 4. It The discharge is made more active by supplying dilution water from the pipe 11 to the reject, if necessary. Further, the foreign matter-removed pulp (liquid containing fine fibers) that has passed through the openings 21 of the porous cylindrical body 5 is accepted as
It is discharged from the undigested material separator through the acceptor outlet connector 3 that communicates with the lower end of the porous cylindrical body 5.

As mentioned above, the device of the present invention can reduce energy consumption by 30% or more with respect to the prior art, and at the same time, can raise the pulp concentration to a low range of MC concentration.
As a side effect, a reduction in wear of the perforated cylinder 5 can be achieved, and a more adjustable device in function and end result is also achieved. For example, only by changing the rotation speed of the porous cylindrical body 5, the apparatus can be adjusted so as to be applicable to maximum different concentrations and different types of pulp. This method
With the added possibility of creating perforated cylinders with ridges of varying slope and variable size apertures, the ultimate optimized undigested separator can be discussed.

The device represents one preferred embodiment according to the invention, the device according to the invention being capable of various variants. In some cases, it is also possible to utilize one or more tilt angles of the ridges, the velocity of the pulp suspension and the velocity of the perforated cylinder may differ from the previous examples, The speed difference specified in the range is 2-2m /
Seconds.

EFFECTS OF THE INVENTION As is apparent from the above description, the undigested material separating apparatus according to the present invention is provided. According to this undigested material separator,
Compared with the prior art, the following advantages are obtained.

The power required to rotate the porous cylinder is sufficiently smaller than that of the conventional device, and the screening efficiency and separation efficiency are equal to or higher than those of the conventional device.

Since the supply direction of the fiber suspension to be treated to the undigested matter separating device is the same as the rotating direction of the porous cylindrical body, the fiber breakage due to contact with the porous cylindrical body is effectively prevented. For the same reason, the perforated cylinders can contribute to improving the quality of the final product without destroying undigested (knots) and other solid particles that would cause trouble in later screening steps.

Since the supply direction of the fiber suspension to be treated is the same as the rotation direction of the porous cylinder, the undigested matter and other solid particles in the fiber suspension to be treated are the same as those in the conventional apparatus on the surface of the porous cylinder. The porous cylindrical body is not worn so much.

[Brief description of drawings]

FIG. 1 is a partial sectional side view of an undigested material separating apparatus according to an embodiment of the present invention. FIG. 2 is a fragmentary plan view of an essential part of the undigested material separating apparatus shown in FIG. FIG. 3 is a vertical cross-sectional view of the undigested material separating device as in FIG. 1, but is a schematic view showing only the main part. FIG. 4 is a cross-sectional view similar to FIG. 2, but FIG. 2 is shown as a cross-sectional view of the essential parts of the undigested material separation device in a state looking down from above, It is the figure shown as a typical cross-sectional view of the undigested material separation device in the state looked up. FIG. 5 is a cross-sectional view of the perforated plate (screen) in the expanded state according to the preferred embodiment, taken along line A- in FIG.
It is a principal part sectional view cut along the A line. FIG. 6 is a development view of a perforated plate (screen), which moves (rotates) toward the lower side of the paper surface in the drawing. 1: Outer housing, 3: Acceptor outlet connector, 4: Rejector outlet connector, 5: Perforated cylinder (cylindrical screen), 6: Stationary blade, 8: Annular space, 29: Raised ridge.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Hannu Lone Cornheu Finland. S-48700 Kiminlin, Remin Kaisenkatsu 20 (56) References JP-A-61-207689 (JP, A) JP-A-61-207690 (JP, A) JP-B-46-37004 (JP, B1)

Claims (7)

[Claims] 1. An outer housing (1) having an inlet connector (2) for treated fiber suspension, an outlet connector (3) for accept, and an outlet connector (4) for reject, comprising:
The outer housing (1) in which the respective connecting bodies are tangentially attached to the outer housing, and a porous cylindrical body supported by a shaft (7) and rotatably disposed in the outer housing ( 5) and one or more stationary blades (6) disposed inside the porous cylinder (5) for separating undigested matter and other solid substances from the fiber suspension In the above apparatus, the porous cylindrical body (5) is rotated in the same direction as the supply direction of the fiber suspension to be treated performed through the inlet connection body (2), and rejected through the outlet connection body (4). Is discharged in the same direction as the rotating direction of the porous cylindrical body (5), and the inlet connector (2) is treated between the outer housing (1) and the porous cylindrical body (5). Outside to supply fiber suspension The porous cylindrical body (5) is attached to the housing (1), and the porous cylindrical body (5) has a plurality of ridges (29) having an inclined surface (25) and parallel to each other, on its outer surface (24), The ridge (29) extends in the direction of inclination with respect to the direction of the axis of rotation of the porous cylindrical body (5) and is minus (-) 45 relative to the straight line parallel to the axis of rotation on the outer surface (24). When the perforated cylindrical body (5) is rotated, the inclined surface (25) hits the fiber suspension and has an inclination angle in the range of from 45 ° to plus (+) 45 °. An apparatus for separating undigested material, which is characterized by acting like being thrown away. 2. The front surface of the raised ridge (29), which is substantially inclined and raised with respect to the outer surface (24) of the porous cylindrical body (5), and the outer surface (24). Right-angled rear surface (2
7) The undigested material separating apparatus according to claim 1, characterized in that 3. The method according to claim 1, wherein the plurality of raised ridges (29) extend in an inclined direction with respect to a rotation axis direction of the porous cylindrical body (5). Undigested material separation device. 4. The undigested material separating apparatus according to claim 1, wherein the openings of the porous cylindrical body (5) are holes or slots. 5. Separation of the undigested material according to claim 1, wherein the difference between the peripheral speed of the porous cylindrical body (5) and the supply speed of the fiber suspension is 2 to 8 m / sec. apparatus. 6. The perforated cylinder, wherein one of the blades (6) for generating a positive pressure or negative pressure pulse is based on a connection center of the reject outlet connection (4) to the outer housing (1). The undigested material separating apparatus according to claim 1, wherein the undigested material separating apparatus is positioned within an angle range of minus (-) 10 ° to plus (+) 45 ° along the circumferential direction of the body (5). 7. One of the blades (6) for generating a positive pressure or negative pressure pulse is based on a connection center of the inlet connector (2) for the treated fiber suspension to the outer housing (1). According to the present invention, the porous cylinder (5) is positioned within an angle range of minus (−) 10 ° to plus (+) 45 ° along the circumferential direction of the porous cylinder (5). Digester separation device.