AT511455B1 - ENERGY SAVING FLOTATION DEVICE AND ENERGY SAVING FLOTATION PROCESS - Google Patents

Abstract

The object of this invention is a flotation cell (1) or a flotation device for separating solids from liquids, in particular for the separation of impurities and ink particles from pulp suspensions. According to the invention, in the flotation cell (1) in each case a ventilated first partial flow (4) and an unventilated second partial flow (3) face one another in front, whereby a turbulent mixing zone (11) is formed. The object of this invention is also a flotation process which is carried out with the flotation cell or flotation device according to the invention.

Description

Austrian Patent Office AT511 455 B1 2012-12-15

description

ENERGY SAVING FLOTATION DEVICE AND ENERGY SAVING FLOTATION PROCESS

The subject of this invention is a flotation cell or a flotation for separating solids from liquids, in particular for the separation of impurities and ink particles from pulp suspensions. The object of this invention is also a flotation process which is carried out with the flotation cell or flotation device according to the invention.

Flotation is a physico-chemical separation process used in different fields. Thus, for example, deinking flotation is a process for separating impurities and printing ink particles from pulp suspensions produced in particular in waste paper processing. This process is linked to the generation of gas bubbles in an appropriate amount and size distribution. Hydrophobic or surface-active hydrophobized solids such as ink particles or stickies are carried by the adhered gas bubbles to the liquid surface where they can be removed as a foam.

With the help of flotation also ores etc. of deaf, unusable material can be separated.

There are already a variety of different flotation known, EP 1 350 888 discloses a flotation device with a plurality of injectors, which are arranged within the flotation cell and through which the aerated pulp suspension is introduced. These injectors are arranged in a row and have a common diffuser and a common baffle plate.

The flotation represents by the great expense of pumping energy is a relatively energy-intensive process.

The baffle plate disclosed in EP 1 350 888 essentially serves to deflect the direction of flow from vertical to horizontal with the side effect of a further mixing of air and suspension, but a large part of the kinetic energy is dissipated into flow turbulences.

A reduction of the energy requirement and an optimization of the cell geometry are therefore desirable.

The invention is therefore an object of the invention to provide a flotation cell or a flotation, which can be operated energy-saving and still sufficient ventilation can be guaranteed.

This object is achieved by a flotation cell to which a ventilated first partial flow and an unventilated second partial flow can be supplied in such a way that meets in the liquid-filled flotation cell of the ventilated first partial flow substantially frontally on the unventilated second partial flow.

The ventilated and unventilated partial flow thus collide head-on in the flotation cell. A baffle plate is no longer provided here, rather the non-ventilated partial flow forms the "baffle plate". for the ventilated partial flow. The non-ventilated partial flow does not need to be vented through its own injector, so much less pump energy is needed.

Due to the collision of the two partial flows, there is the formation of a turbulent mixing zone. The vented partial flow preferably flows from below into the flotation cell and hits the unventilated partial flow, which flows from above into the flotation cell.

For the ventilation of the first partial flow, it is preferable to use a self-acting injector which is located outside the flotation cell and which is optimized with regard to air intake and energy requirement (pressure loss). The unventilated partial flow can flow freely from above into the flotation cell or it is accelerated with a type of nozzle.

Preferably, the flotation cell has a round, preferably circular, cross-section. In a circular cell, the flow or the foam in all directions the same way, there is no "undefined". Deflectors and a central central injector would not be affected by adjacent injectors.

It is also advantageous if the cross section of the at least one flotation cell tapers in the vertical direction downwards.

The invention also relates to a flotation device for separating solids from liquids, wherein the flotation device has a plurality of flotation cells according to one of claims 1 to 5. The individual flotation cells are connected in series so that an accept line of a preceding flotation cell forms a feed line for a subsequent flotation cell.

It is advantageous if the individual flotation cells are arranged one above the other. In this "tower floatation" For example, the accept stream at the bottom of a flotation cell may simply continue to flow into the underlying cell. The first partial flow to be ventilated is branched off in front of the underlying flotation cell and ventilated via an injector.

The height difference between the liquid levels of two superimposed cells would provide a sufficient outflow velocity. One would then have to pump the entire feed stream only once to the highest level. Only the ventilated subsets would have to overcome the resistance of the injectors, this would each use a pump.

The subject of the invention also forms a corresponding method for separating solids from liquids by means of flotation in at least one flotation cell, in particular for the separation of impurities and ink particles from pulp suspensions. The liquid to be floated is divided into at least two partial streams, wherein a first partial flow is vented and a second partial flow is not ventilated. In the liquid-filled flotation cell, the ventilated first partial flow strikes the unaerated second partial flow essentially head-on, so that a turbulent mixing zone forms in this region.

In an advantageous embodiment of the method, the first vented partial flow in the flotation cell flows vertically upwards and bounces in the flotation cell on the unaerated second partial flow, which flows vertically from top to bottom in the flotation cell.

It is advantageous if the first partial flow is ventilated via an injector outside the flotation cell.

Preferably, a plurality of flotation cells are provided, wherein the turbulent mixing zone is formed in each flotation cell and being formed from an accepting flow of a preceding flotation cell of the ventilated first partial flow and the unaerated second Telstrom for the subsequent flotation cell.

In the following the invention will be described with reference to drawings. In the drawings: Fig. 1 is a schematic (side view) of a flotation cell according to the invention; 2 shows a schematic (side view) of the flotation device according to the invention with a plurality of flotation cells arranged one above the other; The same reference numerals in the individual figures relate to the same components.

FIG. 1 shows the flotation cell 1 according to the invention. The flotation cell 1 is filled with the liquid to be floated 2, for example, a contaminated pulp suspension. The flotation cell 1 has a circular cross-section and expands in the present case

Claims (10)

Austrian Patent Office AT511 455 B1 2012-12-15 the example conical upwards. In the upper part of the flotation cell 1, a foam channel 9 is arranged, it surrounds the flotation cell 1 annularly. The flotation cell 1, two partial streams 3 and 14 are supplied. These partial streams 3, 14 consist of the liquid 2 to be floated. The first partial stream 14 is aerated by an injector 5 with air 15. The injector 5 may, for example, be a self-priming injector, that is to say an injector in which the liquid to be floated flows out through a nozzle and draws in air via the Bernoullie effect. The ventilated first partial flow 4 is introduced via the first supply line 20 from below or from the side into the flotation cell 1, so that the ventilated partial flow 4 exits vertically upward from the outlet opening 22 of the first supply line 20. The unventilated partial stream 3 is introduced via the second supply line 19 from above into the flotation cell 1. The outlet opening 21 of the second supply line 19 is arranged opposite the outlet opening 22 of the first supply line 20. In operation, the aerated first partial flow 4 and the unaerated second partial flow 3 collide head-on to form a turbulent mixing zone 11. Below the turbulent mixing zone 11 is a calming and outgassing zone 12 at the bottom of the flotation cell 1 below the zone 12 is the accept line 23, through which the accept current 6 is subtracted. Above the turbulent mixing zone 11 is the collector zone 10, in which the air can spread and has enough time to form the flotation foam 8 above the liquid surface 17. The enriched with impurities and ink particles flotation foam 8 collects in the foam channel 9, from there the overflow 7 is discharged. FIG. 2 shows a flotation device in which a plurality of flotation cells 1 are arranged one above the other in a tower construction. In each of these flotation cells 1, a ventilated first partial stream 4 and an unaerated second partial stream 3 meet. In this case, the accept stream 6 of a preceding flotation cell 1 forms the inlet 23 for the subsequent flotation cell 1. This inlet 23 is divided into a first partial stream 14 and a second partial stream 3. The first partial flow 14 is then aerated by the injector 5 with air 15. Since the first partial flow 14 in the injector 5 must overcome a certain flow resistance, a pump 13 is arranged in each case before the injector 5. In the present example in Fig. 2, the height difference 16 between two superimposed flotation cells 1 is sufficient to provide a sufficient outflow velocity of the unaerated second partial stream 3. In the accept line 23 of each flotation cell 1, a control valve 24 is arranged, which is controlled by a liquid level controller 18, thereby maintaining a constant filling level in the individual flotation cells 1 can be maintained. The embodiments shown in the drawings represent only a preferred embodiment of the invention. The invention also includes other embodiments in which, for example, the individual flotation cells 1 are arranged side by side. Although the unaerated partial flow 3 would also have to be pumped from one cell to the next in such a cell configuration, but with a minimum delivery height. Flotation cell for separating solids from liquids by flotation, in particular for the separation of impurities and ink particles from pulp suspensions, characterized in that the flotation cell (1) each a ventilated first partial stream (4) and an unvented second partial stream (3) can be fed in such a way that, in the flotation cell (1) filled with liquid (2), the ventilated first partial flow (4) strikes the unaerated second partial flow (3) essentially frontally. 3/6 Austrian Patent Office AT511 455B1 2012-12-15 2. flotation cell according to claim 1, characterized in that the first vented partial flow (4) via a first supply line (20) and the second unaerated partial flow (3) via a second supply line (19) can be fed, wherein the outlet openings (22, 21 ) of the two supply lines (20,19) in the flotation cell (1) are arranged opposite one another. 3. flotation cell according to claim 2, characterized in that the outlet opening (22) of the first supply line (20) vertically upwards and the outlet opening (21) of the second supply line (19) points vertically downwards. 4. flotation cell according to one of claims 1 to 3, characterized in that the flotation cell (1) has a round, preferably circular, cross-section. 5. flotation cell according to one of claims 1 to 4, characterized in that the cross section of the flotation cell (1) tapers in the vertical direction downwards. 6. Flotationsvorrichtung for separating solids from liquids by means of flotation, characterized in that the flotation device comprises a plurality of flotation cells (1) according to one of claims 1 to 5, wherein the individual flotation cells (1) are connected in series, so that an accept line (23) a preceding flotation cell (1) forms a feed line (23) for a subsequent flotation cell (1). 7. A method for separating solids from liquids by flotation in at least one flotation cell, in particular for the separation of impurities and ink particles from pulp suspensions, characterized in that the liquid to be floated (2) is divided into at least two partial streams (14, 3) a first partial flow (14) is ventilated and a second partial flow (3) is not ventilated, wherein the ventilated first partial flow (4) in the flotation cell (1) filled with liquid (2) strikes the unventilated second partial flow (3) substantially frontally , so that in this area forms a turbulent mixing zone (11). 8. flotation method according to claim 7, characterized in that the first vented partial flow (4) in the flotation cell (1) flows vertically upwards and that the unvented second partial flow (3) vertically from top to bottom flows into the flotation cell (1). 9. Flotationsverfahren according to claim 7 or 8, characterized in that the first partial flow (14) via an injector (5) outside the flotation cell (1) is vented. 10. Flotationsverfahren according to any one of claims 7 to 9, characterized in that a plurality of flotation cells (1) are provided, wherein in each flotation cell (1), the turbulent mixing zone (11) is formed and wherein an accepting stream (6) of a preceding flotation cell ( 1), the aerated first partial flow (4) and the non-aerated second partial flow (3) for the subsequent flotation cell (1) is formed. For this 2 sheets of drawings 4/6