FI77481C - Strainer. - Google Patents

Description

1 77481 Splitter - Sil

The present invention relates to a sorter which is primarily intended for use in sorting and cleaning pulp, in particular pulp. The screen comprises a housing, a cylindrical screen member inside it, a member moving near the screen surface, a sorting pulp inlet, a reject outlet and a sorted pulp, i.e. an accept outlet.

FI patent No. 67588 discloses a screen drum with a feed opening for the pulp to be sorted at one end and a reject outlet at the other end. The screen also has devices 15 for rotating the sortable mass. The screen surface of the screen drum has grooves on the feed side; the direction of flow in this direction is substantially perpendicular to the grooves. The grooves consist of an upstream side plane, a downstream side plane and a bottom plane. The base plane 20 is substantially parallel to the curtain surface of the screen surface. The bottom levels of the grooves are perforated. The upstream side plane of the grooves is substantially perpendicular to the curtain surface and the downstream side plane forms an angle of 60 ° to 5 ° with the curtain surface. In the preferred embodiment, the angle formed by the curtain surface of the screen plate 25 and the downstream side plane of the grooves is about 30 °.

In the papermaking process, pulp is made by cooking wood, whereupon the wood breaks down into fibers. Because even the wood material of the same wood has different properties, some of the fibers do not separate and are removed as bundles of fibers, commonly referred to as waste or sticks. These form a reject. Other contaminants, such as bark, must also be removed. The sorter must distinguish between unwanted impurities and waste, i.e. reject, from the accepted fraction. In order to avoid significant fiber loss Waste enters the reject, contaminants must be removed efficiently and selectively.

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It is important to note that different applications have different requirements. In some applications, it is important to achieve a high content of long fibers, especially secondary fibers, in the approved fraction, as the long fibers reinforce 5 end products, e.g., paper. In other applications, the opposite is true. In the case of, for example, primary fibers or pulp mill fibers, it is desirable to concentrate the long fibers in the reject for further processing.

10 Target plates and rotors have been extensively studied and it has been found that creating pulsations on the rotor can increase the power of the device. U.S. Patents 3,363,795 and 4,318,805 disclose a drum rotor having a raised surface for pulsations. In the embodiment of U.S. Patent 4,318,805, the protrusions protruding from the surface of the rotor are rods whose expanding ends provide impulses and whose arms do not resist the flow much.

U.S. Patents 4,447,320 and 4,200,537 disclose rotors whose vanes move near the screen surface and provide large positive impulses. Other types of rotors are described in other patents; for example, U.S. Patent 3,726,401 discloses a rotor whose surface protrusions or protrusions produce approximately equal positive and negative impulses. According to this patent, any protrusions can be used as long as the desired impulses are obtained, since the protrusions and the depressions between them produce positive pressure impulses for sorting and negative pressure impulses for cleaning the screen 30.

The rotating member disclosed in U.S. Patent 3,400,820 consists of a plurality of interconnected discrete bodies formed by a selected corrugated structure providing nearly equal positive and negative impulses.

It is an object of the present invention to:

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3 77481 - Provide a rotating member that increases the intensity of the impulses produced near the openings - holes or slits in the sieve plate - to provide the negative impulses required for countercurrent rinsing of the sieve and anti-clogging. In this case, the flow of the fiber suspension through the openings of the sieve increases.

- Provide a rotating member with a high pulse frequency and a sufficient pulse size.

10 - To provide a rotating body that produces sharp and sharp negative impulses and thus high intensity.

- Reduces the need for power.

15 - Provide a rotor that allows the use of smaller holes in the screen, thereby improving sorting efficiency.

- To obtain an acceptance fraction corresponding to the consistency of the mass entering the feed-20 opening as closely as possible.

- To provide wing-like bodies to be used instead of the rotor in certain applications where the continuity of the rotor surface is not desirable; for example, if it is desired to avoid chopping long fibers and when a larger feed sorting zone is more desirable.

- To provide a rotor and wing-like bodies which can most preferably be used in connection with the screen plate described in FI patent no. 68588.

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The stated objects are achieved by a device characterized in that the surface of the rotating member is shaped so that the grooves therein form a first plane parallel to the curtain surface of said surface, an inclined plane forming an angle of 30 ° to 60 ° with the first plane, an upper plane parallel to the first plane and a side plane substantially perpendicular to the first plane.

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It has been found that the particular shape of the rotor surface and the wing-like bodies according to the invention is very advantageous in producing strong impulses and negative impulses sufficient to minimize sieve blockage.

The invention will now be described in more detail with reference to the accompanying drawings, in which Figure 1 shows a known pressure screen using 10 rotating blades for producing impulses, Figure 2 shows impacts applied to the screen by the rotating blades of Figure 1, Figures 3 and 3a show the shape of a rotor surface according to the invention; 4a show impulses produced by a grooved rotor or wing-like bodies according to the invention, as shown in Figures 3 and 5, Figure 5 shows an embodiment in which wing-like bodies are used instead of a rotor and in which the surface shape according to the invention 20 is shown. Figure 7a shows an intensity factor which is the ratio of the change in frequency and the unit of time when a known rotating member is used, Fig. 7a shows an intensity factor when using a rotating member according to the invention, profile comparison.

As shown in Figure 2, the rotating vane members produce both negative and positive impulses. The symbol 0 indicates the value of the pressure near the screen surface or in the sorting zone between the rotating vane and the screen drum. When the pressure of the mass is greater than the reference point 0, the pressure 35 has a positive value with a maximum at point A, and when it is lower than the reference point, the pressure has a negative value with a maximum at point B.

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The previously known rotary vane members according to Fig. 1 produce the impulses shown in Fig. 2. As can be seen from the figure, the front surface of the vane member provides a positive impulse, the maximum value or amplitude of which is reached at just 5 minimum clearances between the member and the screen drum. A positive impulse promotes flow in the sorting zone through the openings in the screen drum, as the flow always occurs from the higher pressure zone to the lower pressure zone. However, after the minimum wing clearance point 10, the largest negative impulse is achieved because the inclination of the wing member changes after the minimum clearance point. As can be seen in Figure 1, this angle of inclination is about 30 ° or even less in most wing members. When the maximum value of the negative impulse is reached, the pressure increases again towards 15 reference points 0. The negative impulses caused by the rotating vane cause intermittent backflow through the openings of the screen drum and thus prevent the accumulation of fibers in the openings. This self-induced countercurrent rinsing is greater the greater the negative oscillation.

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The front surfaces of the vanes or protrusions of previously known rotors and wing-like bodies curve towards the screen drum until the minimum clearance point of the rotor is reached and their rear surfaces curve away from the screen. At the minimum clearance point of the rotor 25, the change in the inclination of the curved surface is 0. Shortly after this point, the negative impulses begin to increase towards their maximum, after which the impulses begin to decrease again, thus repeating the rotation shown in Fig. 2.

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The central idea of the present invention is to provide a rotor and wing-like bodies in which the surface shape of the grooves is determined by a first plane parallel to the curtain surface of the rotor, with a first plane inclined at an angle of 30 ° to 60 °, with a first plane a parallel upper plane and a lateral plane substantially perpendicular to the first plane. In a preferred embodiment, the angle between the first plane and the inclined plane is about 45 °.

In Figures 3 and 3a, reference numeral 1 is the first plane and 5 is the number 2 inclined plane. Number 3 refers to the upper plane and number 4 to the vertical side plane against the first plane. Reference numeral 6 is the curtain surface of the rotor and 7 is the rotor.

In Fig. 5, the same reference numerals 1, 2, 3 and 4 are used to refer to the first plane, the inclined plane, the upper plane and the vertical side plane against the first plane.

As shown in Figure 3a, the surface of the rotor has a first plane 1 parallel to the curtain surface. It then slopes to form a sloping plane 2 until it reaches the upper plane 3. The length of the upper plane 3 should be 1.2 to 7.6 cm. After the upper plane, the groove comprises a side plane 4 perpendicular to the first plane 1. The length of the first level 1 can vary from 0 to 7.6 cm.

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In order to produce impulses by means of which the blockage of the sieve can be prevented more effectively than by means of rotors with a curved surface, it is essential that the side plane 4 is substantially perpendicular to the base plane.

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Fig. 4a shows the impulses generated by the grooved rotating member 7 according to the invention (Fig. 4). The 90 ° angle of the rotor surface or the wing-like bodies produces a very sharp negative impulse. This is due to the rapid change in the direction of fluid flow-30 as well as the Bernouilli phenomenon caused by the increasing velocity of the fluid at the minimum clearance point of the rotor or wing-like body. This sharp or rapid change in impulse makes the rotor or vane-shaped body more efficient at backwashing the screen drum 10. The explanation 35 for this phenomenon is that the maximum velocity and acceleration of the fluid passing through the openings 11 during countercurrent rinsing is higher than that of known impulse generating means.

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7 77481 because the change in pulses or pulse magnitude with respect to time is greater when using a shaped surface.

In the present invention, the term "impulse intensity" 5 means the ratio of the change in impulse magnitude to the unit of time. In other words, the intensity is not only due to the magnitude of the impulse but also depends on the rapid and abrupt change. The intensity factor, IF, is the ratio of the change in impulse magnitude to the unit of time: 10 impulse magnitude / time = amp./t * IF (Figures 7 and 7a)

Comparing Fig. 4a to Fig. 2, the superiority 15 of the grooved, rotating member according to the present invention over known rotors or wing-like bodies is observed. In addition, the slope and the front surfaces of the grooved rotating members cause positive impulses that promote the flow of the fiber suspension through the openings in the screen. The upper surface 3 is needed just above the side plane 4 to provide a rapid impulse change.

Figure 5 shows an embodiment of the invention in which a large sorting zone 8 with a very large open space is required in order for the fed pulp to flow to the entire sorting zone. In this case, the accumulation of long fibers in the reject is minimized and the consistency of the reject is achieved as little as possible, i.e. more long fibers are accepted. In this embodiment, grooved wing-like pieces 9 are used instead of the rotor.

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The shaped surface of the rotating member, the rotor or the wing-like body according to the invention, produces high-frequency impulses. For example, when using a rotational speed of 600 rpm, a pulse frequency of even more than 200 Hz can be achieved. 35 High frequency is advantageous because in this case the fibers do not support the openings so easily and since the impulses are also of sufficient size, countercurrent rinsing takes place. When using a higher β 77481 frequency, the thinner can handle thicker masses.

A comparison of Figures 7 and 7a shows the superiority of the intensity factor of the rotating member 5 according to the invention compared to the known rotating member. In Fig. 8, the impulse profile of the known vane is shown by a broken line and the impulse profile of the grooved rotor according to the invention is shown by a solid line.

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Other advantages of the rotor and the wing-like bodies according to the invention are that they allow both a considerable reduction in the size of the strainer holes without a greater increase in power consumption or loss of long fibers and a high acceptance yield. The consistency of the accept can be kept approximately the same as the consistency of the feed mass.

The rotor shown in Figure 3 and the wing-like body shown in Figure 5 can be used in known screen plates 20 as well as in conjunction with the grooved screen plate shown in Figure 6 according to F1 Patent No. 67588.

Claims (9)

9 77481 An apparatus for sorting pulp, comprising a housing, a cylindrical grooved screen member (10) within it 5, the screen member holes being located substantially in the bottom of said grooves, near the screen member (10) on its grooved side a rotating member (7, 9) moving at a predetermined speed , a reject outlet and a sorted pulp outlet of a sorting pulp inlet 10 from which the pulp is led to a sorting zone formed by a screen member (10) and a rotating member (7, 9), characterized in that the surface of the rotating member (7, 9) is shaped so as to the grooves are formed by a first plane (1) parallel to the curtain surface (6) of said surface 15, an inclined plane (2) forming an angle of 30 ° to 60 ° with the first plane, an upper plane (3) parallel to the first plane and substantially opposite the first plane perpendicular to the side plane (4). 20 Device according to Claim 1, characterized in that the rotating element is a rotor (7). Device according to claim 1, characterized in that the rotating member consists of wing-like bodies (9). Device according to Claim 1, characterized in that the angle between the inclined plane (2) and the first plane (1) is approximately 45 °. 30 Device according to Claim 1, characterized in that the length of the first plane (1) is 0 to 7.6 cm. Device according to Claim 2 or 3, characterized in that the rotating element (7, 9) extends above the screen surface. 10 7 7481 Device according to claim 1, characterized in that the screen member (10) is a cylindrical screen plate, the grooves in the screen surface of which are perforated from the bottom plane on the feed side and form a side plane substantially perpendicular to the curtain surface of the screen surface 5, downstream, 60 ° to 5® from a side plane forming an angle of and a bottom plane substantially parallel to the curtain surface of the screen plate. Device according to Claim 7, characterized in that the downstream side plane of the grooves forms an angle of approximately 30 ° with the curtain surface of the screen surface. Device according to Claim 7, characterized in that the downstream side plane and the upstream side plane of the grooves are connected to one another by a plane substantially parallel to the curtain surface. 20 II 11 77481