DE3209719A1 - METHOD FOR DRAINING MINERAL SUSPENSIONS - Google Patents

Description

HOFFMANN · EITLE & PARTNER

PATENT LAWYERS DR. ING. E. HOFFMANN (1930-1976) DIPL.-ING.W. EITLE DR.RER. NAT. K.HOFFMANN. Dl PL.-I NG. W. LEHN

DIPL.-ING. K.FDCHSLE DR. RER. NAT. B. HANSEN ARABELIA ROAD 4. D-8000 MO NCHEN 81. TELEPHONE (089) 911087. TELEX 05-29-19 (PATHE)

36 549 m / wa - 3 -

LICENCIA TALALMANYOKAT ERTEKESITÖ VALLALAT, BUDAPEST,

HUNGARY

Process for dewatering mineral suspensions

The invention relates to a method for dewatering mineral suspensions.

When preparing for the treatment of minerals, concentrating ores, preparing coal, during slurry work in earthworks, in wastewater treatment, etc., huge amounts of fine sludge or suspensions arise, their drainage and storage in accordance with the increasingly strict regulations of nature conservation cause considerable difficulty and expense.

To solve these problems, several continuous and periodic combined processes with flotation and flake settling worked out. In these processes, various types of frame, pane, Belt and drum sieves, vacuum and press sieves, as well as centrifuges application. It is also known from practice to improve the precipitation with calcium or magnesium hydroxide, as well as coarse aggregate materials, Use sieving aids (e.g. sand) or change the pH value. In the filtration of iron ores the sulfonated organic compounds known from the textile industry have long been used.

Such processes and the facilities required to implement them are described, for example, in DE-PS 26 14 260 and 1,119,826, and U.S. Patents 3,398,093; 2,266,954 and 3,408,293.

However, the solutions known from the prior art do not bring the expected results that correspond to the regulations. An equally important and common disadvantage is that they are very disadvantageous from an economic point of view. Dewatering requires a great deal of energy and takes place in complicated and expensive facilities. In practice, filter surface performances are from 10 to 60 kg / m ² / h. known, the most favorable compositions and optimal granulometric ratios up to 150 kg / m ² / h. can be increased.
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These prior art solutions are under constant research

made necessary for further development. It was recognized by the applicant that the reason for complicating the Filterability or drainability of the sludge and the suspensions in their tendency to thixotropy and in the increase resulting from this tendency the structural viscosity, as well as the large zeta potential between the suspended matter and the medium lies. This creates a large structural moisture content, which can only be removed with a lot of energy and for which considerable investment and operating costs required are.

The invention is based on the knowledge that by changing of the properties at the interface of the floating substances, their tendency to thixotropy and their zeta potential can be eliminated or reduced to a minimum. The structural and the The solvate water content of the suspensions is reduced. The floating substances in the suspension should therefore be mixed with substances that cover their surface and prevent the formation of the sludge structure because the capillary Namely, water is enclosed in this mud structure. Ultimately, it is the substance content of the suspension more hydrophobic, which considerably reduces the performance and energy requirements of drainage.

The ability of the individual materials to increase the hydrophobic property of the substance content of the suspension, can be determined by measuring the CST values of the suspension (CST = capillary suction time). This is in the book by R. S. Galle: "Optimizing the Use of Pretreatment

Chemicals "(Solid Liquid Separation Equipment Scale Up, pages 40 to 82; Upland Press Ltd. Croydon, England, 1976) described in detail. To characterize the drainage promoting agents were used for Molecules the so-called HLB value (Hydrophil-Lypophil Balance) or the H / L value (the ratio of the hydrophilic and the lipophilic portion) introduced. The latter value gives the ratio of the two different ones Proportions of the molecules in percent. This value can be measured on the one hand, and on the other hand from the proportions of Molecules or groups are calculated. The definition of these terms is described in the following references: Griffin, W. C: I. Soc. Cosmetic Chemists 1,311 (1949); Griff in, W. C: I. Soc. Costmetic Chemists 5,249 (1954); Moore, C, Bell, M .: Soap Par Furriery and Cosmetics 29, 893 (1956), Davis, I ..; T .: Proceedings of 2nd International Congress on Surface Activity, Juhäsz, E., Lelkesne, Eros, M .: Felületaktiv anyagok zsebkönyve (Editor: Müszaki Könyvkiado, Budapest (1979)).

The object of the present invention is to provide a method to create for dewatering mineral suspensions, in which not only the inadequacies of the previously known Methods are eliminated, but a substantial improvement in drainage with simpler ones Facilities and can be achieved with much smaller energy requirements.

The above object is thereby achieved according to the invention solved that to the suspension to be dewatered depending on its suspended matter content and molecular

Composition surfactants or a mixture of surfactants are added in an amount of 0.03 to 2% , the surfactants or the mixture of surfactants having an HLB value of 8 to 12 or an H / L value of 50 to 150%, and the suspension is then dewatered in a manner known per se. The importance of this process is that by treating the suspension with the substances that have the given HLB or H / L value, the tendency of the suspended substances in the suspension to thixotropy and to form the sludge structure is substantially reduced, almost eliminated , whereby the moisture binding capacity of the suspended substances in the suspension is considerably reduced. This obviously has a beneficial effect on the performance and energy requirements of the dewatering process.

This beneficial effect can be increased if an ionic suspension is added to the suspension before dehydration chain polymer polyelectrolyte or a non-ionic chain polymer polyelectrolyte with cation character added wherein the polyelectrolyte has a molecular weight of 500,000 or more in both cases.

According to the invention, the surfactants or the mixture of Surfactants with a simple mixer, with a centrifugal pump, by atomization or by film-like contact be added to the suspension. But you can also proceed in such a way - that the treated with the surfactants The suspension is brought to a sliding chute and the polyelectrolyte is added there by trickling.

The dehydration can then according to the invention in one any, known manner in a filter container or a settling container or a funnel-shaped Shrink containers are brought to completion with an appropriate cone angle of 30 °.

However, according to the invention, one can also proceed in such a way that the treated with the surfactants and with the polyelectrolyte and concentrated suspension in a settling trough and an attached vibratory or rotary cylinder Sieve is guided and dewatered there.

The sludge to be dewatered during the technological process or a corresponding suspension are therefore fed into a container, where the surfactants are sprayed or mixed intensively ■ be added to the sludge or suspension. In one case, the one treated with the surfactants is then treated Suspension out of the container into a centrifuge or a vacuum filter and dewatered there. In the other In this case, the treated suspension is brought from the container onto a sliding chute, where the polyelectrolyte is mixed in e.g. by a film-like contact. The suspension coming from the sliding chute then flows into the container of a vacuum filter, in which it drains will.

The suspension coming from the sliding chute and treated with surfactants and polyelectrolyte can also be poured into a Sedimentation trough, whereupon the water from the surface at the end opposite the inflow

320S719

is gradually aspirated and recycled, the concentrated sediment from the bottom of the settling trough guided by a conveyor onto a rotary screen and the material coming from the rotary screen is led to the depository.

The implementation of the method according to the invention is explained in more detail below by means of a few examples.
10

example 1

^R 2i} § ^ 2ifi Sludge, created by the enrichment of phosphate ore from Jordan.

i Clay mineral containing a few percent of rock phosphate, kaolin, halloisite, illite, montmorillonite.

below 0.07 mm - 48% by weight 0.07 to 0.1 mm - 18% by weight 0.1 to 0.125 mm- 34% by weight

SS & iS ^^^ centration ^ 7 00 g / l

Y§ £ wendetes_Tensid2 a mixture of with polyethylene glycol ether formed ester of lauric acid and ester of maleic acid formed with octanol.

- ίο -

Y§Ewendete_Mencjej: 10 kg / t dry material

PolYelektrolYt_mit_Kationcharakter £ methylated derivative of polyacrylamide with a molecular weight of 2 to 5 million.

Y§ £; W§2dete_Menge2, 0/25 kg / t dry material

The aggregate materials are used in an aqueous solution.

The sludge formed during the enrichment of the phosphate ore and described above was fed into a container in which the surfactant was added to the sludge by atomization or by intensive mixing. The sludge was then brought from the container onto a sliding chute, where the polyelectrolyte with cationic character was mixed into the sludge by contacting in a film-like manner. The sludge coming from the sliding chute was then placed in the container of the vacuum disc screen. A vacuum of AP _m ⁼ 0.9 was applied. The filter performance was without aggregate materials 302 kg / m ^a / h. Dry matter.

The CST of the sludge was 52 seconds without treatment.

The CST value of the sludge treated with the surfactant and the polyelectrolyte having a cationic character was 4 seconds. The filter performance was 2,487 kg / m ² / h; the thickness of the cake was 20 mm.

The agent coming from the sieve was removed by a belt conveyor and the water returned.

With the same filter, the filter performance with a cake thickness of 10 mm without treatment was 270 kg / m ² / h, after treatment with the surfactant and the polyelectrolyte with cationic character, the filter performance was 2,790 kg / m ² / h.

The results clearly show that the treatment with the surfactant and the polyelectrolyte Filter performance can be increased 8 to 10 times, even with different cake thicknesses.

Example 2

The same sludge treated in the same manner as in Example 1 was transferred to a settling centrifuge brought. The settling centrifuge was equipped with a Speed of 1000 / minute operated, the centrifugal force inside was 667 g. Result: In the case of untreated sludge, the suspended matter content can increase even after 10 seconds cannot be separated from the water. After treating the mud, the mud will rise after 2 seconds 60% concentrated, which does not change after 10 seconds. The thus compacted sludge was placed on a belt conveyor and the recovered water was returned to the system.

Example 3

Sludge created while working on a mining dump in Yugoslavia.
5

Composition ^ 5% coal

95% clay marl

G £ §nulgmetric_distribution_of_sludge £ less than 0.07 mm - 4% by weight
0.07 to 0.1 mm - 9% by weight
0.1 to 0.125 mm - 23% by weight
0.125 to 0.315 mm - 64% by weight

§ £ lamb concentration2 430 g / l

yerwendetes_Tensidj [ester of polyethylene glycol ether, formed with mixed fatty acids formed when vegetable oils decompose.
20th

i 8 kg / t dry material

2 polyacrylamide with a molecular weight of 2 to 5 million. 25th

yerwendete_Mencje_: 0.20 kg / t dry material

The sludge coming from the cyclone after the coal had been separated out was fed into a container where the surfactant was added by atomizing or by vigorous mixing. Sludge draining from the container was brought to a sliding chute, where by film-like

Contacting the polyelectrolyte with cation character was added. The sludge coming from the sliding chute was introduced into the filter container of a vacuum sieve and filtered there. The vacuum was ΔΡ ™ ⁼ ° / ^{9 bar} · ^The sludge had a without treatment

^1-1 ITl 3rd X

CST value of 80 s and with treatment a CST value of 5 s. Without treatment, the filter performance was 70 kg / m ² / h dry material, after the treatment 1,400 kg / m ² / h. The material coming from the sieve was removed with a belt conveyor and the water returned. The filter cake had a thickness of 20 mm.

Example 4

Rohstoff2 sludge, created while processing a Mining dump in Austria. 20th

Composition! 5% lignite. Mixture of to manufacture clay minerals applicable to fine ceramic and brick industry products.

Granulometric_distribution2_of_sludge_:

below 0.07 mm - 18% by weight 0.07 to 0.1 mm - 25% by weight 0.1 to 0.125 mm - 35% by weight

0.125 to 0.315 mm - 22% by weight 30

Sludge concentration ^ 430 g / l

Surfactant used £ a mixture of formed with octanol detem ester of maleic acid and of with lauric acid des Polyethylene glycol ether formed ester.

Υ§ΕΪ§ικ1§ £ §_? Ί§22§_ £ 9 kg / t dry material

Yerwendeter_PolYelektrolY.ti methylated product of the polyacrylamide with a molecular weight of 2 to 5 million.
10

i 0.20 kg / t dry material

The sludge had a CST of 180 s, with treatment a CST value of 20 s. 15

The mud was mixed with the surfactant and the polyelectrolyte treated as described above and then dewatered with a disc filter, the vacuum Λρ = 0.9 bar

"Max

was. The filter performance for the untreated sludge was 37 kg / m ² / h, for the sludge treated only with surfactant 185 kg / m ² / h. ^{and 250 kg / m 2} / hour for the sludge treated with surfactant and polyelectrolyte. The filter cake had a thickness of 20 mm. The water was also returned here and the filtrate was brought to a dump by belt conveyors.

Example 5
30th

The mud described in the previous example was

- 15

-: ^r > η q 7 ι α

treated with a surfactant or with surfactant and polyelectrolyte (as described above) and then in brought a trough. The water became continuous at the end of the trough opposite the inflow sucked off and the compacted sludge at the bottom of the trough brought by a conveyor to a rotary screen. The filtrate was transferred from the rotary sieve to a belt conveyor and brought to a dump. The recovered water was recycled. 10

Example 6

52l} §t2fii Raw sludge for normal Portland cement production from Läbatlan / Hungary.

SiO ₂ - 20.31 Al ₂ O ₃ - 5.41 Fe ₂ O ₃ - 3.08 CaO - 68.12 MgO - 2.66 SO, - 0.29

Granulometric_distribution_of_sludge _: less than 0.01 mm - 30% by weight
0.01 to 0.065 mm - 60% by weight
0.065 to 0.09 mm - 10% by weight

Sludge concentration ^ 1,430 g / l

3203719

Y§ £ wendetes_Tensid2 one with hexaethylene glycol monooleate formed mixture of the ester of polyethylene glycol formed with myristic acid.

Y§ £ w§n <ä§te_Menge2 6 kg / t dry material

i polyacrylic acid 0.2 kg / t dry material

The filter performance for the untreated sludge in a vacuum disc filter was 134 kg / m ² / h. and 555 kg / m ² / h for the treated sludge. The vacuum applied was ΔP _max = 0.8 bar. 15th

Claims (6)

2203719 HOFFMANN ^: Εΐΐϊ, Ιϋ & PATENTANWÄLTK DR. ING. E. HOFFMANN (1930-1976) - DIPL.-ING.W. EITLE DR. RER. NAT. K.HOFFMANN. Dl PL.-ING. W. LEH N DIPL.-ING. K.FPCHSLE. DR. RER. NAT. B. HANSEN ARABELIA ROAD 4. D-8000 MO NCH EN 81. TELEPHONE (089) 911087. TELEX 05-29619 (PATHE) 36 549 m / wa LICENCIA TALALMANYOKAT ERTEKESITÖ VALLALAT, BUDAPEST, HUNGARY Process for dewatering mineral suspensions PATENT CLAIMS f 1 .J Method for dewatering mineral suspensions, characterized in that, depending on its suspended matter content and molecular composition, surfactants or a mixture of surfactants in an amount of 0.03 to 2% are added to the suspension to be dewatered, the surfactants or the mixture of surfactants has an HLB value of 8 to 12 or an H / L value of 50 to 150%, and the suspension is then dehydrated in a manner known per se. 10 2. The method according to claim 1, characterized in that to the suspension before An ionic chain polymer polyelectrolyte or a non-ionic chain polymer also dehydrate Polyelectrolyte with cation character is added, the polyelectrolyte in both Cases has a molecular weight of 500,000 or greater. 3. The method according to any one of the preceding claims, characterized in that the Surfactants or the mixture of surfactants with one simple mixer with a centrifugal pump Atomization or by film-like contacting of the suspension can be added. ' 4. The method according to any one of the preceding claims, characterized in that the suspension treated with the surfactants on a Sliding chute is brought where the polyelectrolyte is added by trickling. 5. The method according to any one of the preceding claims, characterized in that the drainage in a filter tank or a settling tank or a funnel-shaped shrink container with an appropriate cone angle of 30 ° is carried out. 6. The method according to any one of claims 1 to 4, characterized in that with the surfactants and / or with the polyelectrolyte treated and concentrated suspension in a settling trough and in a subsequent vibration or rotation cylindrical sieve is guided and dewatered there.