DE2807481A1 - Flotation of ore or coal slurry using injected air - already mixed with atomised flotation aids to improve flotation - Google Patents

Abstract

Flotation method for bringing coal or ore or other material to the surface of a slurry comprises injecting finely divided air bubbles mixed with flotation aids into the slurry. Pref. the flotation aids are finely atomised by a nozzle to mix them with the air. The pref. droplets size of the flotation aids is 10-100(40-60) mu. The mixing of the flotation aids in the slurry is improved.

Description

Description The invention relates to a flotation process for flotation of substances distributed in a sludge, in particular of coal or ore, in which air in finely divided form and flotation aids are added to the turbidity The flotation of ore or coal is carried out in flotation cells that contain reagents to be added as a blotation aid The amount of flotation aid is Very small in relation to the amount of turbidity, for example 1 1 of reagents per 15,000 1 Cloudy Because of the small amount, the reagents are usually added by dripping the reagents into the pulp inflow to the flotation cells In some cases, reagents are also dripped directly into the individual lotation cells Mix by the action of the stirrer common in ore and coal flotation the flotation reagents with the pulp, so that the reagents at the interfaces between the air bubbles that form due to the fine distribution of the air, and the dull can work The invention is based on the object to improve and simplify the mixing of the blotation reagents with the slurry. In particular, a more uniform and faster distribution of the reagents is intended can be achieved at the interfaces between the air bubbles and the turbidity.

The object is achieved in that the flotation aids at least partially mixed with the flotation air. This measure achieves that the flotation aids are finely distributed and at their place of action, d.

H. the air bubbles into which the turbidity is introduced. surprisingly can thus reduce the amount of necessary flotation aids compared to the previously known Dropping into the slurry or into the slurry inflow can be further reduced. It is Another advantage is that the flotation aid is already in the first cell completely distributed in the flotation pulp, so that it is also in the first cell there is no incorrect discharge.

In one embodiment of the invention it is provided that the flotation aids the flotation air are mixed in finely atomized and that the atomization is preferred takes place through a nozzle. This configuration of the method is advantageous simply load the airflow through the flotation aid evenly. Farther is prevented by a fine atomization that reagents on the air-carrying Parts of the flotation cells, e.g. B. in the hollow shaft of the stirrer, reflected. It is thus ensured that actually the total amount of reagents that the Flotation air flow is supplied, continuously finely divided into the flotation pulp entry.

In a further embodiment of the invention it is provided that the droplet size of flotation aids between 10 and 100 t, in particular between 40? and 60 t. In the range between 10 T and 100 t, favorable ones arise Drops that are perfectly carried along by the air stream without the need for atomization becomes too high. The range £ 40 to £ 60 /, in which with commercially available atomization devices an economical and at the same time with respect to the occurrence of droplets that are too large, reliable atomization is possible.

In a further embodiment of the invention it is provided that the flotation aids the flotation air are admixed upstream of the device that contains the flotation air in the murky distributed. This results in a particularly simple one Admixture, which can advantageously be maintained and monitored during operation, without z. B. the stirrer would have to be shut down.

In a further embodiment of the invention it is provided that the atomization and admixing takes place intermittently, in particular by a piston pump. By intermittent admixing can also be advantageous for the very small amounts an exact dosage of reagents can be achieved. A small piston pump is a particularly inexpensive metering element that easily achieves the required atomization pressure brings up. A subsequent turbulence ensures that the air that is in passes the admixing point for the reagents at the introduction-free intervals, comes into contact with the air laden with reagents and mixes with it will. This results in spite of the intermittent supply of the reagents an effect that corresponds to a continuous feed.

A flotation cell is used to carry out the flotation process provided, which has a sludge container and preferably a stirrer with a hollow shaft as a supply organ for the flotation air having, the flotation cell a device for adding the flotation aids to the flotation air, preferably a nozzle. This configuration provides a device for implementation of the flotation process according to the invention are available, in particular for the Flotation of coal or ore is suitable.

In an embodiment of the flotation cell it is provided that the device for admixing the flotation aid arranged in the hollow shaft of the stirrer is. This results in an embodiment which has the advantage that the way of the introduced flotation aids in droplet form up to the turbidity only is short, so that the droplets will clump together to form larger droplets with certainty is omitted. The droplet size can therefore be relatively large.

In another embodiment it is provided that the device for admixing the plotting aid is arranged in the air line to the hollow shaft of the stirrer is. This results in an arrangement that is particularly easy to assemble and to wait is.

It is also provided that the connection part of the air supply line is designed as a swirl chamber on the hollow shaft.

This configuration is particularly advantageous when used as a metering device a piston pump is used for the flotation aid and the atomization takes place in the air supply line. Without constructive effort it can be done in spite of intermittent Atomization ensures a uniform supply of flotation aids to the pulp.

It is also provided in one embodiment of the invention, that the device for admixing the Elotationshilfsmittel as a Venturi nozzle or is designed as a pressure atomizer nozzle. These two types of nozzles have been used for the atomization of the olefins used as flotation aids as special proven favorable. With them, a fine atomization according to the invention is in the usual way possible in the desired droplet size range.

The invention is explained in more detail with reference to drawings.

The drawings show in detail: Fig. 1 a Admixing arrangement with a pressure atomizing nozzle in the hollow stirrer shaft and Fig. 2 an admixing arrangement with a nozzle in the bus feed line to the stirrer.

In the admixing arrangement according to FIG. 1, 1 denotes the atomizer nozzle, which is arranged in the lower part of the hollow stirrer shaft 2. At the bottom of the hollow stirrer shaft 2, the stirrer 3 is indicated. The flotation aids are the nozzle 1 is fed through the feed line 4, which is preferably coaxial in the stirrer shaft 2 is arranged. At the upper end of the stirrer shaft, the drive not shown in detail is, the stirrer shaft is mounted in bearings 5. In camps 5 they are not either Seals shown in more detail for the space 6 arranged in which the air supply pipe 7 opens. In the area of the space 6, the hollow stirrer shaft 2 has a passage 8 for the supply air from line 7, through which the air from line 7 into the Stirrer shaft 2 arrives. In the upper part of the agitator shaft 2, the bearing 9 is arranged, which leads the supply line 4 and at the same time seals the stirrer shaft 2 to the outside.

In the admixing arrangement according to FIG. 2, the guide indicated is with 10 and denotes the hollow stirrer shaft with 1-1. The guide shaft 11 has on her upper end a cover 12, which seals it to the outside, and is in the bearings 13 stored.

The bearings 13 have an unspecified seal for the Space 14, which is at the height of the passage 15 as a vortex chamber, the guide shaft 11 encloses. The flotation air is fed to the stirrer shaft 11 via line 16, which opens into the space 14 at the level of the passage 15. The lead 16 for the In its mouth part in front of the space 14, flotation air has an atomizing nozzle 18 on which the flotation aids are finely distributed in the air flow of the air supply line 16 brings in. The atomizing nozzle 18 is connected to a pump 19 through the line 17 connected, which are preferably located in or on the flotation aid container 20 is located.

The pump 19 can be both continuously operating Pump, such as a gear pump or similar, act as an intermittent one Pump in the manner of a single-point pump, in which, for example, a small piston over a camshaft is set in motion. With such a pump there is a change in stroke a particularly simple and precise metering of the flotation auxiliary quantities is possible.

A complex bypass and / or speed control is not necessary. The space 14 forms a swirl chamber in which the reagent-laden Air mixed with the unloaded air, so that in spite of the intermittent addition the liquid droplets are evenly distributed in the flotation air.

The method according to the invention is not restricted to use only Flotation cells equipped with stirrers are limited. The inventive Mixing can also be carried out with stirrerless flotation cells. Decisive is always that an even, fine distribution of the flotation reagents in the Flotation air is achieved. The number of droplets should be at least the Correspond to the number of air bubbles, but it is better to be a multiple thereof.

Claims (12)

Flotation process Claims 1. Flotation process for flotation of substances distributed in a sludge, in particular of coal or ore, in which the pulp I; uft in finely divided form and flotation aids are added, d u r c h e k e n n n z e i c h n e t that the flotation aids at least partially mixed with the flotation air. 2. flotation process according to claim 1, characterized in that the flotation aids are admixed with the flotation air in finely atomized form and that the atomization is preferably carried out through a nozzle (1, 18) 3. Flotation process according to claim 1 or 2, characterized in that the droplet size of the flotation aid between 10 ß and 100 kt, in particular between 40 / and 60 /, is set. 4. Flotation process according to claim 1, 2 or 3, characterized in that that the flotation aids are admixed with the flotation air upstream of the device (3, 10) that distributes the flotation air in the pulp. 5. Flotation process according to claim 1, 2, 3 or 4, characterized in that that the atomization and admixture of the flotation aids intermittently, in particular by a piston pump (19). 6. flotation process according to claim 1, 2, 3, 4 or 5, characterized in that that subsequent to the admixture of the flotation aids to the flotation air a swirl takes place. 7. Flotation cell for carrying out the flotation process according to Claim 1, 2, 3, 4, 5 or 6, with a cloud container and preferably a stirrer (3, 10) with a hollow shaft (2, 11) as the supply element for the flotation air, characterized in that that the flotation cell has a device for admixing the flotation aids for flotation air, preferably a nozzle (1, 18). 8. flotation cell according to claim 7, characterized in that the Device for adding the flotation aids in the hollow shaft (2) of the stirrer is arranged. 9. flotation cell according to claim 7, characterized in that the Device for admixing the flotation aids in the air line (16) for Hollow shaft of the stirrer is arranged. 10. Flotation cell according to claim 7, 8 or 9, characterized in that that the device for admixing the flotation aids as a pressure atomizer nozzle is trained. 11. Flotation cell according to claim 7, 8 or 9, characterized that the device for admixing the flotation aids is designed as a Venturi nozzle is. 12. Flotation cell according to claim 7, 9, 10 or 11, characterized in that that the connection part of the air supply line (16) to the hollow shaft (11) as a vortex chamber (14) is formed. - Description -