CN1831160A - Method for inhibiting scale-forming during the process of leaching nickle from nickle-contg. laterate by sulfuric acid - Google Patents
Method for inhibiting scale-forming during the process of leaching nickle from nickle-contg. laterate by sulfuric acid Download PDFInfo
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- CN1831160A CN1831160A CNA2006100764311A CN200610076431A CN1831160A CN 1831160 A CN1831160 A CN 1831160A CN A2006100764311 A CNA2006100764311 A CN A2006100764311A CN 200610076431 A CN200610076431 A CN 200610076431A CN 1831160 A CN1831160 A CN 1831160A
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Abstract
The invention relates to a treatment method for lateritic nickeliferous iron ore. It uses magnetic field, surface activator and microwave radiation to restrict the produce of fouling. Because adding suitable quantity of copper ion, it could effectively improve the leaching efficiency of nickel. It has rapid reacting speed, low power consumption and is suited to distilling nickel from lateritic nickeliferous iron ore.
Description
Technical field
The present invention relates to a kind of treatment process of nickel-bearing laterite, exactly, the present invention relates to a kind of method that sulfuric acid leaches fouling in the nickel-bearing laterite process that suppresses.
Background technology
The reserves of world's continental rise nickel are about 4.7 hundred million tons, and wherein about 35% exists with the sulphide ores form, and about 65% exists with the oxidized ore form.Because nickel oxide ore selecting and smelting technology difficulty is big, so present 70% nickel is to extract from sulphide ores.Along with the world economy high speed development, the nickel increase in demand, price increase, but and the nickel sulfide ore resource of economic utilization is exhausted day by day, people increase day by day to the degree of concern of nickel oxide ore.
Several Technologies of existing mature processing nickel oxide ore are as follows, and for nickeliferous height and the low laterite of cobalt, the method that more employing electric furnace reduction is smelted is produced ferronickel or nickel matte, this method energy consumption height, and can not reclaim cobalt.When handling the laterite nickeliferous, that cobalt is all higher relatively, adopt wet method to leach more, be beneficial to comprehensively reclaim various valuable metals.According to the height of ore neutral and alkali content of magnesia, there is ammonia to soak and two kinds of technologies of acidleach respectively.Ammonia leaching process is applicable to and contains the high ore of magnesium oxide, and whole flow process nickel recovery is 75%-80%, and the rate of recovery of cobalt is lower, about 40%-50%.Contain the low ore of magnesium oxide because need not consume a large amount of acid go in and the basic gangue in the ore, so adopt the sulfuric acid leaching.In the practical application, under High Temperature High Pressure, carry out usually, the rate of recovery 90%-95% of this method nickel, the rate of recovery 80%-90% of cobalt soaks flow process and firing method process apparently higher than ammonia.But this method still exists practical problemss such as the steam heating energy consumption is big, and extraction time is long, and the interior fouling of autoclave is serious.
CN1552922A provides a kind of method with low-grade nickel oxide in the sulphuric acid extraction snake mosquito stone, the leaching of heating, leach liquor solid precipitation agent coprecipitated nickel hydroxide metal under normal pressure.But because the nickel metal is to be present in the mineral with the state that chemistry is contaminated, so normal pressure leaches separately, the leaching yield of nickel does not reach ideal state, and is unreasonable economically.
Use microwave heating to have plurality of advantages, micro-wave energy has the selectivity heat effect to material, and has katalysis to inhaling ripple material chemical reaction.The micro-wave energy of material absorbing almost 100% is converted into heat effect, so the thermo-efficiency height of microwave heating, to inhale the temperature rise of ripple material very rapid.Therefore, microwave heating is obtaining attention aspect the nickel oxide ore processing.
CN1057489A relates to a kind of novel method of selecting oxide ore with the microwave heating treatment difficulty.Use microwave heating sulfuration in plasma gas (N gas current-carrying) smelting furnace melting, obtains high ice nickel, and the cobalt metal also has the good rate of recovery simultaneously.But this method needs the nickel oxide rich ore of Ni>3.5%, and is inapplicable for the lower laterite of a large amount of grades undoubtedly, and energy consumption height, cost height.
CN1031256A has disclosed the method that a kind of microwave heating plasma desulfuration is handled the ambrose alloy oxide ore, to obtain high ice nickel.But it is Ni5%, Cu4%, S25% that this method requires handled concentrate composition, comes down to low-grade nickel oxide ore mixed with high-grade nickel sulfide concentrate to use, and is not suitable for a large amount of low-grade nickel-bearing laterites equally.
US5535992-A proposes a kind of High Temperature High Pressure and leaches the autoclave device that laterite is used, and is formed by connecting by multistage autoclave.This method inevitably produces a large amount of foulings, must remove fouling by phased manner.
When handling the laterite nickeliferous, that cobalt is all higher relatively, prior art adopts wet method to be beneficial to comprehensively reclaim various valuable metals more.According to the height of ore neutral and alkali content of magnesia, there is ammonia to soak and two kinds of technologies of acidleach respectively.Ammonia leaching process is applicable to and contains the high ore of magnesium oxide, and whole flow process nickel recovery is 75%-80%, and the rate of recovery of cobalt is lower, about 40%-50%.Contain the low ore of magnesium oxide because need not consume a large amount of acid go in and the basic gangue in the ore, so adopt the sulfuric acid leaching.In the practical application, under High Temperature High Pressure, carry out usually, the rate of recovery 90%-95% of this method nickel, the rate of recovery 80%-90% of cobalt soaks flow process apparently higher than ammonia.
In traditional sulfuric acid pressurized acid leaching technical process,, under the high-temperature and high-pressure conditions of 3~5MPa, with dilute sulphuric acid valuable metals such as nickel, cobalt are dissolved with iron, aluminium mineral and to enter solution at 230~270 ℃.But in the pressurized acid leaching process, contain a large amount of aluminium, iron and silicon in the solution, along with the carrying out of reaction, aluminium, iron and silicon all can sedimentations, stick to autoclave courage and inner-walls of duct, thereby reduce the useful volume of autoclave, blocking pipe.Fouling runs up to a certain degree can have a strong impact on production, must constantly carry out the scale removal operation and just can keep production and normally carry out.For example in the Mao A of Cuba factory, the scaling rate of autoclave is 300mm/a, and average every month need time scale removal in 5 day.In addition, can increase thermal resistance after the formation fouling, because the thermal conductivity of fouling is low, heat transfer coefficient be descended, the heat transfer coefficient of heat utilization system is low, makes hot-fluid can not get effective utilization, and the result certainly will consume the heat of external heat source too much, the increase energy consumption.Up to the present also do not find a kind ofly can effectively solve the method for fouling.
Many deficiencies at present nickel-bearing laterite treatment process, especially in order effectively to solve the technical barrier of fouling, we find to add suitable tensio-active agent in the sulfuric acid leaching process of laterite through studying for a long period of time, apply the generation that the action of a magnetic field and microwave radiation can effectively suppress fouling.When the present invention can guarantee the leaching yield of valuable metals such as nickel, cobalt, effectively suppress the generation of fouling, shorten extraction time, cut down the consumption of energy, reduce the operation easier that leaches reaction.
Summary of the invention
The object of the invention is to provide a kind of method that sulfuric acid leaches fouling in the nickel-bearing laterite process that suppresses.
Inhibition sulfuric acid of the present invention leaches the method for fouling in the nickel-bearing laterite process, it is characterized in that: the liquid-solid ratio according to 2: 1~6: 1 is made into ore pulp, sulfuric acid concentration is 50g/l-200g/l in the control ore pulp, add an amount of tensio-active agent and bivalent cupric ion and stir, the consumption of tensio-active agent is 10 of an ore quality
-6Doubly to 10
-3Doubly, the add-on of cupric ion is 10mg/l-5g/l in the leach liquor, the ore pulp for preparing is placed in the magnetic field stops 1min-30min and carry out magnetic field treatment, then ore pulp is packed into and leach in the reaction vessel, in leaching process, carry out microwave radiation, temperature of reaction was 60 ℃-140 ℃ when normal pressure leached, extraction time 10min-120min; Temperature of reaction was 110 ℃-280 ℃ when high pressure leached, and pressure is 110kPa-5000kPa, extraction time 10min-120min.Handled nickel-bearing laterite is limonite type or low magnesium noumeite type, contains Ni0.3~4%; MgO%≤15%.Use microwave generating apparatus, by waveguide the microwave that produces is imported and leach internal tank, institute's employing container is high pressure vessel or non-pressure vessel.The microwave frequency that adopts is 915MHz or 2450MHz.The magnetic field of adopting is electromagnetic field, and field intensity is 1~10
4MT.Microwave power during leaching is 0.5~20kW.Adopt sulphuric acid soln to leach laterite, the sulfuric acid consumption is 0.1 times to 1 times of ore quality.Described tensio-active agent is one or more in sulfonate or the vitriol.
Leaching process can carry out with following dual mode.
1, single stage method leaches.
Ore pulp is positioned over interior leaching of autoclave that the material (as tetrafluoroethylene) to microwave is made, and leaching condition is: under 915MHz or 2450MHz microwave radiation, and 110 ℃-280 ℃ of controlled temperature, extraction time 10min-120min.
2, two-step approach leaches.
The first step is positioned over ore pulp in the non-pressure vessel that the material (as glass, polyvinyl chloride etc.) to microwave makes, under 915MHz or 2450MHz microwave radiation, and 60 ℃-140 ℃ of controlled temperature, extraction time 10min-120min.To leach slurry afterwards and change in the high pressure vessel, temperature is controlled at 110 ℃-280 ℃, and pressure-controlling is carried out the heavy iron operation of leach liquor at 110kPa-5000kPa.
In second step, after leaching was finished, through liquid-solid separation, valuable elements such as nickel, cobalt were present in the filtrate, and the separation and Extraction in back step just can adopt methods such as industrial mature extracting and separating or sulfide precipitation to carry out.
Embodiment
The invention will be further described below by embodiment.
Embodiment 1: get the 100g laterite, size mixing by 2: 1 liquid-solid ratio, sulfuric acid concentration is
200G/l adds the tensio-active agent Sodium dodecylbenzene sulfonate of 0.1mg and the copper sulfate of 2mg, stops in intensity is the magnetic field of 200mT
10Min, under the microwave radiation of 2450MHz, microwave power 0.5kW, normal pressure leaches 120min under 60 ℃ temperature, and the nickel leaching yield is 92%, and no fouling produces.
Embodiment 2: get the 100g laterite, liquid-solid ratio by 4: 1 is sized mixing, sulfuric acid concentration is 130g/l, add the tensio-active agent Sodium dodecylbenzene sulfonate of 10mg and the copper sulfate of 200mg, in intensity is the magnetic field of 1mT, stop 30min, under the microwave radiation of 2450MHz, microwave power 2kW, normal pressure leaches 40min under 140 ℃ temperature, and the nickel leaching yield is 94%, and no fouling produces.
Embodiment 3: get the 100g laterite, size mixing by 6: 1 liquid-solid ratio, sulfuric acid concentration is
90G/l adds the tensio-active agent Sodium dodecylbenzene sulfonate of 100mg and the copper sulfate of 3g, is 10 in intensity
4Stop in the magnetic field of mT
1Min, under the microwave radiation of 2450MHz, microwave power 1kW, normal pressure leaches 60min under 100 ℃ temperature, and the nickel leaching yield is 93%, and no fouling produces.
Embodiment 4: get the 100g laterite, size mixing by 3: 1 liquid-solid ratio, sulfuric acid concentration is 140g/l, adds the tensio-active agent Sodium dodecylbenzene sulfonate of 1mg and the copper sulfate of 30mg, stops in intensity is the magnetic field of 500mT
5Min, under the microwave radiation of 2450MHz, microwave power 1kW, under 110 ℃ temperature, high pressure leaches 120min under the 110kPa pressure, and the nickel leaching yield is 95%, and no fouling produces.
Embodiment 5: get the 100g laterite, size mixing by 4: 1 liquid-solid ratio, sulfuric acid concentration is
100g/l adds the tensio-active agent Sodium dodecylbenzene sulfonate of 10mg and the copper sulfate of 2g, stops in intensity is the magnetic field of 100mT
8Min, under the microwave radiation of 2450MHz, microwave power 2kW, 1000kpa leaches 60min under 180 ℃ temperature, and the nickel leaching yield is 96%, and no fouling produces.
Embodiment 6: get the 100g laterite, size mixing by 6: 1 liquid-solid ratio, sulfuric acid concentration is 80g/l, adds the tensio-active agent Sodium dodecylbenzene sulfonate of 50mg and the copper sulfate of 3g, is 10 in intensity
4Stop 1min in the magnetic field of mT, under the microwave radiation of 2450MHz, microwave power 4kW, 5000kPa leaches 10min under 280 ℃ temperature, and the nickel leaching yield is 96%, and no fouling produces.
Embodiment 7: get the 100g laterite, liquid-solid ratio by 3: 1 is sized mixing, sulfuric acid concentration is 140g/l, add the tensio-active agent Sodium dodecylbenzene sulfonate of 50mg and the copper sulfate of 1g, in intensity is the magnetic field of 100mT, stop 10min, under the microwave radiation of 915MHz, microwave power 20kW, normal pressure leaches 30min under 120 ℃ temperature, and the nickel leaching yield is 92%, and no fouling produces.
Embodiment 8: get the 100g laterite, size mixing by 3: 1 liquid-solid ratio, sulfuric acid concentration is 130g/l, adds the tensio-active agent Sodium dodecylbenzene sulfonate of 10mg and the copper sulfate of 1g, stops in intensity is the magnetic field of 300mT
6Min, under the microwave radiation of 915MHz, microwave power 20kW, 4000kPa leaches 20min under 260 ℃ temperature, and the nickel leaching yield is 95%, and no fouling produces.
Embodiment 9 (Comparative Examples): get the 100g laterite, size mixing by 3: 1 liquid-solid ratio, sulfuric acid concentration is 130g/l, and 4000kPa leaches 60min under 260 ℃ temperature, and amount of scale buildup is 10
2Mg.Add the tensio-active agent Sodium dodecylbenzene sulfonate of 10mg or stop 8min in intensity is the magnetic field of 300mT, 4000kPa leaches 60min under 260 ℃ temperature, no fouling generation.
Claims (8)
1, a kind of method that suppresses fouling in the sulfuric acid leaching nickel-bearing laterite process, it is characterized in that: by 2: 1-6: 1 liquid-solid ratio is sized mixing, sulfuric acid concentration is 50g/l-200g/l in the control ore pulp, add an amount of tensio-active agent and bivalent cupric ion and stir, the consumption of tensio-active agent is 10 of an ore quality
-6Doubly to 10
-3Doubly, the add-on of cupric ion is 10mg/l-5g/l in the leach liquor, the ore pulp for preparing is placed in the magnetic field stops 1min-30min and carry out magnetic field treatment, then ore pulp is packed into and leach in the reaction vessel, in leaching process, carry out microwave radiation, temperature of reaction was 60 ℃-140 ℃ when normal pressure leached, extraction time 10min-120min; Temperature of reaction was 110 ℃-280 ℃ when high pressure leached, and pressure is 110kPa-5000kPa, extraction time 10min-120min.
2, method according to claim 1 is characterized in that: handled nickel-bearing laterite is limonite type or low magnesium noumeite type, contains Ni0.3~4%; MgO%≤15%.
3, method according to claim 1 is characterized in that: use microwave generating apparatus, by waveguide the microwave that produces is imported and leach internal tank, institute's employing container is high pressure vessel or non-pressure vessel.
4, method according to claim 1 is characterized in that: the microwave frequency that adopts is 915MHz or 2450MHz.
5, method according to claim 1 is characterized in that: the magnetic field of adopting is electromagnetic field, and field intensity is 1~10
4MT.
6, method according to claim 1 is characterized in that: the microwave power during leaching is 0.5~20kW.
7, method according to claim 1 is characterized in that: adopt sulphuric acid soln to leach laterite, the sulfuric acid consumption is 0.1 times to 1 times of ore quality.
8, method according to claim 1 is characterized in that: described tensio-active agent is one or more in sulfonate or the vitriol.
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Cited By (5)
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CN102080156B (en) * | 2009-11-30 | 2013-04-10 | 四川大学 | Microwave and additive assisted method for drying and roasting nickel laterite |
CN103725889A (en) * | 2013-12-16 | 2014-04-16 | 金川集团股份有限公司 | Method for leaching copper and nickel in leaching slag of matte/ice nickel with assistance of microwave |
CN105408507A (en) * | 2013-07-26 | 2016-03-16 | 艺康美国股份有限公司 | Utilization of temperature heat adsorption skin temperature as scale control reagent driver |
CN108823430A (en) * | 2018-07-11 | 2018-11-16 | 山东大学 | A method of promoting lateritic nickel ore leaching nickel and cobalt using surfactant |
CN117083401A (en) * | 2023-06-29 | 2023-11-17 | 青美邦新能源材料有限公司 | Multistage descaling system and multistage descaling method in laterite nickel ore high-pressure leaching process |
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DE3140380C2 (en) * | 1981-10-10 | 1985-04-11 | Gebrüder Sulzer AG, Winterthur | Process for the extraction of nickel, high-purity magnesium oxide and cement |
CN1303230C (en) * | 2005-06-03 | 2007-03-07 | 北京矿冶研究总院 | Pressure oxidation leaching method for nickel-cobalt oxide ore |
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2006
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Cited By (8)
Publication number | Priority date | Publication date | Assignee | Title |
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CN102080156B (en) * | 2009-11-30 | 2013-04-10 | 四川大学 | Microwave and additive assisted method for drying and roasting nickel laterite |
CN105408507A (en) * | 2013-07-26 | 2016-03-16 | 艺康美国股份有限公司 | Utilization of temperature heat adsorption skin temperature as scale control reagent driver |
CN105408507B (en) * | 2013-07-26 | 2017-03-29 | 艺康美国股份有限公司 | The method for suppressing the dirt accumulation on the surface contacted with liquid medium |
US10316394B2 (en) | 2013-07-26 | 2019-06-11 | Ecolab Usa Inc. | Utilization of temperature heat adsorption skin temperature as scale control reagent driver |
CN103725889A (en) * | 2013-12-16 | 2014-04-16 | 金川集团股份有限公司 | Method for leaching copper and nickel in leaching slag of matte/ice nickel with assistance of microwave |
CN108823430A (en) * | 2018-07-11 | 2018-11-16 | 山东大学 | A method of promoting lateritic nickel ore leaching nickel and cobalt using surfactant |
CN108823430B (en) * | 2018-07-11 | 2020-04-28 | 山东大学 | Method for promoting laterite-nickel ore to leach nickel and cobalt by using surfactant |
CN117083401A (en) * | 2023-06-29 | 2023-11-17 | 青美邦新能源材料有限公司 | Multistage descaling system and multistage descaling method in laterite nickel ore high-pressure leaching process |
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