FI122400B - Flotation cell and method for deinking a fiber suspension - Google Patents

Description

Flotation cell and method for deinking a fiber suspension

Background of the Invention

The invention relates to a flotation cell comprising at least one flotation basin and at least one acceptor assembly for directing out a-5 septic flow in the flotation basin out of the flotation cell.

The invention further relates to a method for de-inking a fiber suspension, the method of introducing a fiber suspension flow and a gas into a flotation cell to a flotation cell, separating a fiber suspension flow into a flotation pool into an accept flow and a rejection flow.

Flotation cells are used to remove ink and any other impurities and ash from a fiber suspension made from disintegrated and sorted recycled paper, also known as de-inking. The aim of the deinking process is to produce as white and pure 15 recycled fibers as possible. Flotation cells are used in flotation decontamination, whereby the flotation is carried out in the cells by adding a soap or other foam-inducing surface tension reducing chemical as a flotation chemical to a dilute approximately 1% fiber suspension. The dyeing suspension may be fed into a flotation cell flotation basin via an injector in which air is mixed with the fiber suspension flow through the injector. However, another gas or gas mixture may be used instead of air. The dyeing suspension may also be fed to a flotation cell having a separate aeration of the fiber suspension. The ink and impurities adhere to the air bubbles in the flotation pool, which rise to the surface of the fibrous pension in the flotation pool, whereby the ink and impurities can be removed as a reject stream by overflow or scraping. The accept stream from the flotation tank, i.e. the stream of fiber suspension purified from impurities, is discharged

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v from the flotation cell through its acceptor junction. U.S. Patent Nos. 4,726,897 and 6,920,983 disclose certain flotation cells.

| One problem with flotation cells is the uneven flow field of the accept flow in the flotation basin, i.e., the amount of accept flow that occurs at different cross-sections of the flotation basin.

° Typically, the amount of accept flow is greater in the longitudinal direction of the flotation pool at the accept site and smaller away from the accept site. The aseptic assembly is generally located longitudinally in the center of the flotation basin so that the amount of accept flow is greater in the center of the flotation basin than at its edges.

2 This, in turn, results in different flow rates and flow fields for each injector, for example, in flotation cells with multiple injectors. Similar problems in flow field control also occur in flotation cells provided with separate aeration of the fiber suspension.

5 Problems with flow field control, in turn, cause the quality of the accept to deteriorate if the de-inking capacity in the flotation cell is not reduced, so that the total number of flotation cells used for de-inking, for example, must be further increased to achieve the desired deinking capacity.

BRIEF DESCRIPTION OF THE INVENTION It is an object of the present invention to provide a new type of flotation cell that provides a more uniform flow field for a flotation cell in a flotation basin.

The flotation cell according to the invention is characterized in that the flotation cell further has at least some distance between the flotation basin and the acceptor line for flowing the accept flow from the flotation basin to the acceptor direction as separate flows from at least one portion of the flotation and at least or one or more changes of direction and / or length are arranged such that the pressure drop across the flow paths of the accept flow is substantially equal.

The method according to the invention is characterized in that the accept flow flowing from the flotation basin to the acceptor passage is conducted at least on a portion of the distance between the flotation basin and the acceptor passage as separate flows such that the pressure paths equal.

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V The flotation cell comprises at least one flotation basin and at least one accept site for conducting a flow of separation in the flotation basin | 30 out of the flotation cell. The flotation cell further has at least some portion of the distance between the flotation basin and the acceptor flange for separate flow paths of the accept flow from the flotation basin to the acceptor flange in separate streams for at least some portion of the flotation basin and the acceptor flange. The minimum cross-sectional area and / or one or more direction changes and / or lengths of said flow paths are arranged such that the pressure drop across the flow paths of the accept flow is substantially equal.

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When at least some portion of the distance between the flotation container and the acceptor flange have separate flow paths for flowing the accept flow from the flotation basin to the acceptor flange as separate flows for at least some portion of the flotation basin and the acceptor flange and suitably with respect to the corresponding properties of the other flow paths, separate flow paths are provided in which the flow pressure drop across each flow path is substantially equal or equal. As a result, the flow field of the accept flow in the floatation pool is leveled off, smoothing the flow field of the flow of accept between the edges and the middle of the flotation pool. This, in turn, smooths or aligns the flow and flow fields for said injectors in the flotation cells provided with the injectors, which in turn further increases the deinking capacity so that the size of the flotation-15 thiocell does not have to be increased or the required deinking capacity can be achieved. This, in turn, reduces the equipment costs of deinking and the energy consumption of deinking.

According to one embodiment, the flotation cell comprises at least some portion of the distance between the flotation tank and the acceptor outlet to separate the flow of acceptor flow from the direction of the flotation basin to the acceptor as separate flows for at least some portion of the a plurality of direction changes and / or lengths are arranged between the flow channels so that the pressure drop of the accept flow in the flow paths formed by the flow channels between the flotation basin and the accept flow is substantially equal.

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According to another embodiment, the flotation cell further comprises at least one accept opening in the flotation vessel for conducting a distinct flow of accept 30 through the accept opening and out of the flotation vessel. and flowing cell out of the flotation cell, and that the flotation cell comprises at least some portion of the flow path between the accept opening and the accept mouth for conducting the flow of the accept opening from the direction of the accept opening into separate flows at least and / or one or more direction changes and / or lengths 4 are arranged between the flow channels such that the pressure drop of the accept flow on the flow paths formed by the flow channels between the accept opening and the accept port is substantially equal.

According to a third embodiment, the flotation cell further comprises at least one acceptor collection space for conducting at least one acceptor flow through an acceptor opening to an acceptor collection space and further through an acceptor collector to receive an acceptance flow out of the flotation cell, and directionally to the acceptor direction as separate flows at least at some portion of the distance between the acceptor aperture and the acceptor port and that the minimum cross-sectional area and / or one or more directional changes and / or lengths of said flow channels are adapted between sometimes there is essentially one uniform.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments of the invention will be explained in more detail in the accompanying drawings, in which Figure 20 schematically shows a top view of a flotation cell, Figure 2 schematically shows a top view of the flotation cell of Figure 1, the flotation cell is viewed from above ™ obliquely, and Figs.

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o some possible embodiments of the tectonic sensor.

In the figures, some embodiments of the invention are shown in simplified form for clarity. Similar parts are denoted by like reference numerals in the figures.

m o ° Detailed Description of the Invention

Figure 1 is a schematic view of a flotation cell 1 viewed from above, and Figure 2 is a schematic view of a flotation cell 1 according to Figure 1, viewed from above. In Figures 1 and 2, the flotation cell 1 is shown in an outline view so that for clarity some of the outline of the structure of the flotation cell 1 is omitted and some of the structures of the flotation cell 1 may be visible through other structures of the flotation cell 1. The flotation cell 15 has a flotation basin 2 which provides a volume into which a stream of fiber suspension to be cleaned is conducted or fed through one or more injectors 3. The injectors 3 are shown schematically in Figure 2. In the injector 3, air is mixed with the fiber suspension flow to the flotation tank 2. In general, 10 air is supplied to the flotation basin to remove ink and impurities, but it is also possible to use another gas or gas mixture instead of air, and for the purposes of this specification, the term gas refers to various gases or gas mixtures, such as air. The structure and function of the various injectors are well known to those skilled in the art and will not be further discussed herein. The fiber suspension viral 15 can also be introduced into the flotation tank 2 of the flotation cell 1 through something other than the injector 3 if the injectors are not in use. In the flotation basin 2, the ink and any other impurities are trapped in the air bubbles which rise to the surface of the fiber suspension in the flotation basin 2, whereby the ink and impurities can be removed, for example by overflow or scraping, for reject treatment. For the sake of clarity, such overflow or scraping is not shown in the figures.

The flotation basin 2 further has an accept opening 4 which in the flotation cell 1 of Figs. 1 and 2 is located at the bottom of the flotation basin 2. The accept flow from the flotation basin 2, i.e. the impurity-purified fiber suspension flow, passes through the accept opening 4 to the accept collection space 5, from where it further passes through the accept port 6 to the accept channel 7 and further 5 in the mass production process.

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1, the accept opening 4 in the flotation cell 1 according to Figures 1 and 2 has an? 30 in the general flow direction of the accept flow, i.e., the leading edge 4 'of the accept opening 4 and towards the general flow direction of the accept flow | the rear edge 4 'of the accept opening 4 disposed in the opposite direction, i.e. away from the accept port 6. In the longitudinal direction of the flotation cell 1, the flotation basin 2 ra-o g extends to the ends or end walls 2 ', 2' of the flotation basin 2. One flotation cell can? comprising one or more phases at least partially separated by a volume of one or more partitions in a volume of one or more flotation cells. In the embodiment shown in Figures 1 and 2 6, the flotation cell 1 comprises only one step for clarity.

Flow guides 8 further form the acceptor collection space 5 of the flotation cell 1 according to Figures 1 and 2, together with the wall, ceiling and bottom structures, i.e. walls, of the acceptor collection space 5, within a distance or distance that the accept flow is conducted in the accept collection space 5 along a portion of the distance between the accept opening 4 and the accept opening 6 from the accept opening 4 to the accept opening 6 as separate flows. The flow channels 9 thus form separate flow paths in the acceptor collection space 5 for part of the distance or distance between the acceptor opening 4 and the acceptor connection 6.

In the solution of Figures 1 and 2, the flow guides 8 extend from the front edge 4 'of the accept opening 4 as seen in the flow direction 15 illustrated by the arrow A of the accept flow, only for part of the distance between the accept opening 4 and the accept port 6 Thus, separate flows passing through the flow channels 9 flow into a uniform volume upstream of the acceptor compound 6 in the acceptor collection space 5. However, the flow channels 9 could also be formed such that the flow channels 9 extend apart from one another to the accept port 6, whereby the flow guides 8 are adapted to extend from the front edge 4 'of the accept opening 4 to the accept port 6. The accept flow would then be conducted as separate flows from the accept opening 4 to the accept port 6 as viewed in the downstream direction of the ak-25 septic flow. The flow guides 8 may be formed, for example, as plate-shaped baffles which may be positioned vertically, i.e. parallel to the height direction of the accept collecting space 5.

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but which baffles may also be disposed in an oblique position v with respect to the height of the accept bin 5. The baffles, due to their construction and material, can be adapted to control the flow | in addition, they also reinforce the structure of the acceptor collection space 5.

The minimum cross-sectional area of each flow channel 9 and / or one or more directional changes and / or lengths, i.e. the minimum cross-sectional area of each flow channel 9 in the flow direction and / or the length and / or complexity of the other flow channels 9 area and / or length and / or complexity such that the pressure drop across the flow paths formed by all flow channels 9 between the accept opening 4 and the accept port 6 including the accept port 6 is substantially equal or equal. Thus, in the solution, a space or spaces are formed between the flotation basin and the acceptor junction so that the flow of accepting flow is separated from each other by different flow paths, characterized by flow paths with minimum cross-sectional lengths and that the pressure drop between the flotation basin and the acceptor joint formed by the separate flow paths is substantially equal, whereby the flotation basin generates a uniform accept flow 10 across the length of the flotation basin.

The pressure drop caused by the flow paths formed by the flow channels 9 can be influenced by the size of the minimum cross-sectional area of the flow channel 9 and / or the length of the flow channel 9 and / or one or more changes in direction. The smaller the minimum cross-sectional area of the flow passage 9, the greater is the pressure drop across the flow path formed by the flow passage 9 and vice versa. Further, the longer the flow passage 9, the greater the pressure loss in the flow path formed by the flow passage 9 due, for example, to the flow resistance caused by the flow controllers 8 and the structures of the accept collection space 5 and vice versa. In addition to flow resistor 20, the length of the flow guides 8 for some of the flow controllers 8 also affects the amount of backflow of the flow after the flow guide 8, causing a loss of turning pressure on the flow path after the flow passage 9. Further, the greater the steepness of the change in direction, the greater the pressure loss due to the change in direction of the flow.

By designing or dimensioning a minimum cross-sectional area and / or one or more directional changes and / or lengths of each flow channel 9 relative to the corresponding properties or features of the other flow channels 9,

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providing separate flow channels 9 that form tamil along the flow paths between the accept port 4 and the accept port 6, including the accept flow at a pressure drop of substantially equal to or equal to one another | planes being equal. As a result, the flow field of the accept flow was accepted by the acceptor. At age 5, flattening, which further smoothes the flow field of the accept flow at the aco [g] septic port 4, for example, reduces or eliminates the amount of accepted flow flowing from the accept port 4 back to the flotation vessel 2. As a result, for example, the difference in the accept flow rate in the middle of the float container 2 compared to the accept flow 8 at the edges of the float container 2 will at least be reduced and may even disappear completely. This, in turn, smoothes or harmonizes the flows and flow fields in the flotation tank 2 in the area of influence of each injector 3. As a result of better control over the internal flow fields of the flotation cell 1, the deinking capacity can be increased without having to increase either the size of the flotation cell 1 or the total number of flotation cells 1 used to achieve the desired deinking capacity. Thus, the solution further reduces the cost of decontamination as well as energy consumption. As a result of this solution, the performance of accepting flotation cells of different sizes with respect to one another remains substantially constant, which facilitates the design of deinking systems.

According to one embodiment, the flow guide 8 is substantially straight from the initial portion, i.e., from the front edge 4 'of the accept opening 4 to the accept port 6, i.e. the flow guide 8 comprises a direct portion, i.e. the first straight portion 8a, of the accept collection space 5. Under the influence of the first direct portion 8a of this flow guide 8, the flow direction of the accept flow is substantially unchanged at the beginning of the flow channel 9. This, in turn, provides a smoother flow profile for the accept opening 4, which both reduces the flow of air into the accept and smoothes the flow fields in the flotation basin 2 in the area of influence of each injector 3.

In the solution shown in Figures 1 and 2, the flow guides 8 further comprise a curved portion 8b disposed after the first straight portion 8a when viewed in the flow direction. Due to the effect of the curved portion 8b, the direction of flow of the accept stream flows in particular from the ends of the accept bin 5 towards the accept port 6, which is advantageous in the accept tap space 5 narrowing in its width direction according to Figs.

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After the curved portion 8b, as viewed in the direction of flow of the accept flow, the flow guide 8 may also, depending on its intended location in the eaves 5 of the accept 30, also comprise a second straight portion 8c which further | directs the accept flow towards the accept compound 6.

By forming the said straight and curved flow guides 6

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the portions may be affected by the length and complexity of the flow channel 9. By designing a flow channel of a certain length with a minimum size of 35 cross-section and a certain number of straight and curved portions, a pressure drop of the desired flow of 9 is obtained along the flow path created by each flow channel 9.

Fig. 3 schematically shows another flotation cell 1 as viewed from above. In Figures 3, the flotation cell 1 is shown as an outline image-5, so that for clarity some of the outline of the structure of the flotation cell 1 is omitted and some of the structures of the flotation cell 1 may be visible through other structures of the flotation cell 1. In the embodiment of the flotation cell 1 according to Fig. 3, the flow guides 8 are arranged to extend in the region of the accept opening 4 up to the rear edge 4 "of the acceptance opening 4, i.e. the flow guides 8 are also arranged to extend over the dimension of the acceptance opening. In the height direction of the flotation container 2, said flow guide 8 is adapted to extend to the upper surface of the accept opening 4 but could be arranged to extend only a portion of the height of the accept opening 4 in the height direction of the flotation container 2. The flow controllers 8 thus together with the other structure of the accept port 4, at least partially, already form the flow channels 9 in the region of the accept port 4. With such an embodiment of the flotation cell 1 it is possible to smooth the accept flow by means of the flow guides 8 already in the accept port 4 and thus further advantageously influence the internal flows or flow fields of the flotation tank 2. The accept port 4 may be divided by the flow guides 8 into, for example, as many at least partially separated portions as the injectors 3 in the flotation cell 1. It is also possible to have the flow controllers 8 only in the dimension or range of the accept opening region 4 but not extending accept acceptor mode 5.

Figure 4 is a schematic view of a third flotation cell 1 25 viewed from above. In Fig. 4, the flotation cell 1 is shown in contour view, so that for clarity some of the outline o of the structure of the flotation cell 1 is omitted and some of the structures of the flotation cell 1 can be seen in the flotation.

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^ through other structures of thiocyte 1. In the embodiment of the flotation cell 1 τ according to Fig. 4, the flow guides 8 are arranged to extend partially into the flotation basin 2, i.e. the volume of the flotation basin 2, in the height direction of the flotation basin ° 30 2. I do. This is schematically illustrated in Figure 4, where, for the sake of clarity, only flow patterns adjacent to ends 2 ', 2' of flotation basin 2 are shown.

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g its guides 8 partially extend to the volume of the flotation basin 2, although preferably all flow guides are implemented in the same manner. The flow controllers 8 ^ 35 thus together with the other structure of the flotation basin 2, at least partially, form the flow channels 9 in the area or volume of the flotation basin 2. In the upward direction, the flow controllers 8 may also be dimensioned such that completely separated pool volumes are formed in the flotation basin 2, whereby a portion or portions of the flotation cell can be decommissioned without disturbing the flotation cell flows, thereby increasing the ability to adjust flotation capacity. With such an embodiment of the flotation cell 1, it is possible to smooth the accept flow by means of the flow guides 8 already in the volume of the flotation basin 2, which further preferably influences the internal flows or flow fields of the flotation basin 2. The volume of the flotation tank 2 can be divided by the flow controllers 8 into, for example, as many partially separated volumes as there are 10 injectors 3 in the flotation cell 1.

Also, an embodiment is possible in which the flow guides 8 are only in the volume of the flotation basin 2 but do not extend into the area of the accept opening 4 nor the accept collection space 5.

One alternative, in addition to the minimum cross-sectional area and / or one or more directional changes and / or lengths of the flow passage 9, is to effect a pressure drop across or along the flow path such that the flow guides 8 are positioned and dimensioned that each flow channel 9 produces an equal or equal average flow velocity at the end 4 of the accept opening 20 of the flow channel 9. In this case, Qi / Ai = Ui_mean = constant, where Qi is the volume flow of the accept flow into the accept box 4 [m3 / s] and Ai is the surface area of the accumulator opening i [m2]. As a result, the accept opening 4 can be divided into several portions of different sizes. This is schematically shown in Fig. 5, which is a schematic top view of a fourth flotation cell 1. In the flotation cell 1 of Fig. 5, the accept opening 4 is divided into six portions by flow guides 8, i.e., viewed from above as portions 4a, 4c, 4c, 4c, 4c. , 4b and 4a, wherein the portions bearing the same reference cv ^ have substantially the same surface area.

T between the portions of the accept opening 4 referenced by the reference numerals 4c, a flow controller may not be necessary because the distance between the flotation basin 2 ends 2 ', 2 "| on the fictitious centerline CL, which divides the length of the flotation basin 2 or the flotation cell 1, the accept flow flows in the direction o g of the accept connection 6 perpendicularly! with respect to the trailing edge 4 'of the accept opening 4.

? Fig. 6 is a schematic top view of a fifth flotation cell 1. In the flotation cell 1 of Fig. 6, the initially uniform acceptance aperture 4 is divided by flow guides 8 into six equal portions, designated by reference 4d. Here, the volume flows of the accepta flow for each individual portion 4d of the accept opening 4 are substantially equal.

Fig. 7 is a schematic top view of a sixth flotation cell 1. In the flotation cell 1 of Fig. 7, the initially uniform accept opening 4 is divided by flow guides 8 into seven portions, i.e. portions 4e, 4f, 4g, 4h, 4i, 4j and 4k areas are different. In the flotation cell 1 of Figure 7, the aforementioned portions 4e, 4f, 4g, 4h, 4i, 4j and 4k of the accept opening 4 are disposed 10 asymmetrically with respect to the centerline CL. With this embodiment, a particular point in the structure of the floating cell 1 can be reinforced by the flow guide 8. With such a solution, too, the flow paths of the accept can be obtained with the same pressure-loss and uniform flow to the flotation tank. The asymmetrical positioning of the portions of the aseptic opening 4 relative to the centerline CL allows for optimal structural support of the other mu-15 flotation cell.

Fig. 8 is a schematic top view of a seventh flotation cell 1. In the flotation cell 1 of Fig. 8, the accept opening 4 is divided into portions 4I and the accept flange 6 is disposed asymmetrically with respect to the centerline CL of the flotation basin 2 Due to the asymmetric acceptor collection space 5 shown in Fig. 8, the flotation cell 1 can also be placed in a space where it is not possible to place a flotation cell with a symmetric acceptor collection space. In addition, the asymmetric acceptor collection mode allows for variations in pipeline placement.

Fig. 9 is a schematic top view of a ninth flotation cell 1. In the flotation cell 1 of Fig. 9, a portion of the vir-5 flow controllers 8 is arranged in the accept collection state 5 to start immediately

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The front edge 4 'of the accept opening 4' towards the accept side 6 but part of the flow guides 8 is arranged to start in the direction of the accept flow A only 30 ° after the front edge 4 'of the accept opening 4, whereby | the distribution between different flow channels 9 or flow paths may still be affected. 9 also shows the additional controllers 10 located in the accept box 5. The additional controllers 10 are disposed in the downstream direction of the accept flow, as viewed after the flow channels. The additional guides 10 can enhance the effect on the accepta flows, as in the embodiment of Fig. 9, for example, to equalize the accept currents of the flow paths corresponding to the outermost flow channels 9 even after the flow channels 9 have ended. In addition, additional guides can support the structure of the accept collection space 5.

Fig. 10 is a schematic top view of a ninth flotation cell 1. The flotation cell 1 of Fig. 10 has one uniform accept opening 4, which is however shaped such that the width of the accept opening 4, i.e. the distance between the front edge 4 'and the rear edge 4' in the direction of the centerline of the flotation cell 1 towards the ends 2 ', 2' of the flotation basin 2, wherein the accept opening 4 is at its narrowest at the centerline CL of the flotation knob 10 or flotation basin 2 and at its widest at the ends of the flotation basin 2. Thus, the collection width of the accept opening 4 increases as the longitudinal direction of the flotation cell moves from the centerline CL of the flotation cell 1 towards the ends 2 ', 2 "of the flotation cell 1. The variable area of the accept port 4 constricts the accept septum flow at a certain point of the accept port the more the smaller the area of the accept port 4 at that particular point. The solution compensates for possible differences in the flow of the accept flow through the accept opening 4 between the middle part of the flotation basin 2 and the ends 2 ', 2' through the accumulator 2 and thereby accepts separate flow rates the pressure drop is substantially the same between the accept port 4 and the accept port 6 including the accept port 6.

Fig. 11 is a schematic top view of a tenth flotation cell 1. The flotation cell 1 of Fig. 11 has a plurality of separate accepting apertures 4 having a collection width and area 25 increasing in the longitudinal direction of the flotation cell 1, i.e. . The effect of the floating cell 1 of Figure 11 on the accept flow is similar to that of Figure 10

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Effect of the flotation cell 1 according to ^ on the accept flow. In a flotation cell 1 such as that shown in Figure 11, a single accept opening 4 may also result in one or more separate flow paths of accept flow in the accumulator septum. channel.

In the case of Figures 10 and 11, for the accept flow for the flotation tank and

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There is only one space between the accepting junction, which is limited only by the walls surrounding the space. In the embodiments of these Figures, separate flow paths are not separated into physically separate paths, but flow path lengths for accepting flows from different locations are formed by separate flow paths with minimum cross-sectional, directional, and between the acceptor junction is substantially equal.

Fig. 12 is a schematic top view of an eleventh flotation cell 1. In the flotation cell 1 of Fig. 12, the ac-septal opening 4 is divided into six sections, i.e. sections 4m, 4n, 4o, 4p, 4q, and 4r, of which sections 4m and 4n are shaped. such that the collection width of said portions increases towards the 2 "heads 2" of the flotation basin, thereby providing a solution to compensate for the ak-10 septic flow through that portion of the accept opening.

The embodiment of Fig. 12 also shows the flow equalizers 11, which are located in the flow channels 9 provided in the accept collecting space 5, but in addition or instead of this, the flow equalizers 11 could also be located in the accept opening 4 or portions thereof. The flow equalizers 11 may be located in one or more flow channels, either one or more pieces.

The flow equalizers 11 are disposed at least to some extent in the transverse direction with respect to the flow direction A of the accept flow in the flow path formed by the flow channel 9 in question. The flow equalizers 11 equalize the flow 20 by utilizing at least some of the transverse flow areas relative to the accept flow, which may be implemented, for example, as an open plate surface or utilizing various reductions and expansions, which may even be adjustable. Hereby, for example, the size, shape or number of holes in the flow equalizer 11 realized as a perforated plate or even the size or shape of the perforated plate itself can be adjusted. When using the flow equalizer 11, the basic principle is to place the smallest flow cross-section and the farthest largest cross-section near the accept port 6, i.e. in the longitudinal direction of the flotation cell 1, at the accept port 6.

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^ ta area. A very good aspect of such an acceptance flow equalization is that, ideally, the volume flow through the various portions of the acceptance opening is stabilized to a constant θ. The flow equalizer 11 allows the shape and setting of the flow guide 8 to be made in addition to providing one of the possible ways of obtaining the desired minimum cross-sectional area of the flow passage 9, o g The accept port 4 is preferably adapted to extend into the flotation basin 2? over the entire distance between the ends 2 ', 2 "or the end walls 2', 2", either by flow guide guides 8 divided into portions, such as in Fig. 6, or in unified form, such as shown in Figs. 1 and 2. also has a beneficial effect on the flow field of the accept flow, particularly in the vicinity of the 2 'and 2' ends of the flotation pool 2. However, it would also be possible to use an embodiment of the flotation cell 1 where the accept opening 4 would not extend over the entire distance 5 between the end walls 2 'and 2' of the flotation basin 2, which feature should then be taken into account.

Also, an embodiment of the flotation cell 1 is possible in which the flotation cell 1 does not comprise a special acceptor collection space 5. In such an embodiment of the flotation cell 1, such that the accept flow exiting the accept opening 4 from the flotation basin 2 traverses at least a portion of the distance between the accept opening 4 and the accept port 6 as separate flows. Also in this embodiment, the minimum cross-sectional area and / or length and / or one or more directional changes in said flow channels, i.e. said tubes or other structures, are arranged between the flow channels such that the pressure drop across the flow paths of all flow channels is substantially equal or equal. Also in this embodiment, the accept opening 4 can be divided by the flow controllers 8 into at least partially separate portions and into the flow channels 9 already formed in the region of the accept opening 4.

Also, an embodiment of the flotation cell 1 is possible in which the flotation cell 1 does not comprise a special accept box 5 nor a specific accept port 4. In such an embodiment of the flot cell 1, flow channels separated from one another, e.g.

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form flow paths between the flotation basin 2 and the acceptor connection 6 such that through the open ends of the flotation basin 2 ° 30 of said tubes or other structures, the actuator leaves the flotation basin 2 | the septic flow passes at least a portion of the distance between the flotation container 2 and the accept port 6 as separate flows. Also in this embodiment, the g flow channels of said g, i.e., said pipes or other similar structures, the nominal cross-sectional area and / or length and / or one or more directional changes in the direction of the flow are arranged between the flow channels such that the pressure drop across the flow paths formed by all flow channels is substantially equal or equal. In this embodiment too, the volume of the flotation basin 2 can be divided by the flow controllers 8 into partially separate portions and into the flow channels 9 already formed in the area or volume of the flotation basin 2.

In some cases, the features set forth in this application may be used as such, despite other features. On the other hand, the features disclosed in this application may be combined, if necessary, to form different combinations.

The drawings and the description related thereto are intended only to illustrate the idea of the invention. The details of the invention may vary within the scope of the claims.

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Claims (12)

A flotation cell (1) for decolorizing a fiber suspension, said flotation cell (1) comprising at least one flotation basin (2) and at least one accepting assembly (6) for discharging an accepting stream separated in the flotation basin (2) from the flotation cell (1), characterized in that the flotation cell (1) further exhibits at least a portion of the distance between the flotation basin (2) and the accepting assembly (6) from each other separate flow routes for the flow of the accepting stream from the accepting basin (2) 6) direction as separate currents from each other at least on a portion of the distance between the flotation basin (2) and the accepting assembly (6) and that the minimum cross-sectional area of the flow path and / or one or more directional changes and / or length is arranged so that the pressure loss of the accept current the flow routes are essentially the same. Flotation cell according to Claim 1, characterized in that the flotation cell (1) comprises at least a portion of the distance between the flotation container (2) and the accepting unit (6) separated from each other flow channels (9) to direct the acceptance flow from the flotation pool. one (2) direction in the direction of the accepting unit (6) as separate currents from each other at least on a section of the distance between the flotation basin (2) and the accepting unit (6) and that the minimum cross-sectional area of the flow channels (9) and / or one or more directional changes and / or length is provided between the flow channels (9) such that the loss of pressure of the acceptance flow on the flow routes formed by the flow channels (9) between the flotation basin (2) and the accepting assembly (6) is substantially the same. 3. A flotation cell according to claim 1 or 2, characterized in that the flotation cell (1) further comprises at least one accept opening (4) to guide the acceptance current separated into the flotation basin (2) via the accept | The opening (4) out from the flotation basin (2) and further via the accepting assembly (6) out from the flotation cell (1) and that the flotation cell (1) comprises at least on a section of the distance LO ° between the accepting opening (4) and the accepting assembly (6). ) from each other separated flow channels (9) to direct the acceptance current from the direction of the acceptance opening (4) in the direction of the accepting unit (6) as separate from each other separate flows at least at some section of the distance between the accepting opening (4) and the accepting unit ( 6) and that the minimum cross-sectional area of said flow channels (9) and / or one or more directional changes and / or lengths are arranged between the flow channels (9) so that the loss of pressure of the accepting stream formed on the flow routes formed between the flow channels (4) and the acceptance opening (4) the accept aggregate (6) is substantially the same. Flotation cell according to claim 3, characterized in that the flotation cell (1) further comprises at least one accept collection space (5) for conducting the acceptance stream which is separated in the flotation basin (2) via the acceptance opening (4) into the acceptance collection space (5). and further via the acceptance collection space (5) to the accepting assembly (6) to direct the acceptance stream out of the flotation cell (1) and that the flotation cell (1) comprises at least in the acceptance collection space (5) at least on a section of the distance between the acceptance opening (4). the accepting unit (6) separated from each other flow channels (9) to direct the accepting stream from the direction of the accepting opening (4) in the direction of the accepting unit (6) which separates from each other separately at least on a section of the distance between the accepting opening (4) and the accepting unit (6). the minimum cross-sectional area of said flow channels (6) and / or one or more directional changes and / el lengths are provided between the flow channels (9) so that the loss of pressure of the accept stream on the flow routes formed by the flow channels (9) between the accept opening (4) and the accepting assembly (6) is substantially the same. 5. A flotation cell according to claim 4, characterized in that in the acceptance collection space (5) the flow controller (8) is arranged to form in the accepting vessel (5) separate flow channels (9). O Flotation cell according to claim 5, characterized in that the CM 2 flow control means (8) are arranged to extend at least partially to the region of the accept opening (4). ° 30 Flotation cell according to claim 6, characterized in that the flow control means (8) are arranged to extend at least partially to the area of the flotation container (2). O Flotation cell according to any one of claims 5-7, characterized in that the flow control means (8) comprises in its section placed in the accept collection space (5) a substantially straight section (8a) starting from the accept opening (4). front edge (4 ') directed in the direction of the accepting assembly (6). Flotation cell according to any of the preceding claims, characterized in that at least one flow channel (9) has been placed at least one flow equalizer (11), which is arranged at least in some men in a transverse direction in the flow of current (in the flow of acceptance current). ). A method of decolorizing a fiber suspension in which a fiber suspension stream and gas are routed to a flotation cell (1), the floating pool (2), the fiber suspension stream to be directed to the flotation pool (2) is separated into an accepting stream and a reject stream, and the acceptance current is discharged from the flotation cell (1) via the acceptor assembly (6) of the flotation cell (1), characterized by the acceptance current flowing from the flotation basin (2) in the direction of the acceptor assembly (6), at least at a section of the distance between the flotation path (2). the accepting unit (6) which separates from each other in separate currents such that the loss of pressure arising on the flow routes of said separated from each other between the flotation basin (2) and the accepting unit (6) is substantially the same. Method according to claim 10, characterized in that the acceptance current is discharged from the flotation basin (2) via at least one acceptance opening (4) in the flotation basin (2) and that the acceptance current flowing from the flotation basin (2) in the accepting unit (2) 6) direction is at least directed along a section of the distance between the accept opening (4) and the accept assembly (6) which separate from each other separately, so that the loss of pressure occurring on said from each other separates the current routes of flow between the accept opening (4) and acceptance. The aggregate (6) is substantially the same. ° 30 12. A method according to claim 11, characterized in that ac- the accept current flowing through the at least one accept port (4) into the accept collection space (5) of the flotation cell (5) and the 0 accept stream flowing from the flotation basin (2) in the direction of the acceptor assembly (6) leads to the at least one portion of the accept ( 4) and the accept assembly (6) in the accept collection compartment (5) separating from each other separate streams, such that the loss of pressure resulting from said separate streams of flow between the accept opening (4) and the accept assembly (6) in the accept collecting compartment (5) is substantially equal. . δ (M i o CD O X and CL h- · O CD m o δ {M