CN216155494U - System for harmless and full element resource of secondary aluminium ash - Google Patents

Abstract

The utility model provides a system for harmless treatment and full-element recycling of secondary aluminum ash, which comprises a secondary aluminum ash pretreatment device, a hydrolysis reaction device, a tail gas treatment device, a first filtering device, a steam stripping deamination device, a first reaction device, a second filtering device, a second reaction device, a third filtering device, a third reaction device, a fourth filtering device, a fourth reaction device, an evaporative crystallization device, a fifth reaction device, a sixth reaction device, a fifth filtering device, a seventh reaction device and a sixth filtering device; the method converts the aluminum nitride nitrogen in the aluminum ash into ammonia and aluminum hydroxide after hydrolysis, recovers the ammonia to prepare 20% ammonia water, and utilizes the nitrogen resource in the aluminum ash to the maximum benefit.

Description

System for harmless and full element resource of secondary aluminium ash

Technical Field

The utility model relates to the technical field of environmental protection, in particular to a system for harmless and recycling treatment of secondary aluminum ash.

Background

The aluminum ash is an industrial waste, generally produced in the aluminum first supply production process of aluminum electrolysis, aluminum smelting and the like, the content of aluminum and oxides in the aluminum ash can reach 80%, and the lost aluminum accounts for about 1-12% of the total loss of aluminum in the production process. At present, the harmless and resource utilization of the industrial solid wastes such as aluminum ash and the like in China is still in the stage of initial exploration just starting, so that the research and development of the additional value resource technology are urgently needed to be accelerated, and the comprehensive utilization efficiency of the industrial solid wastes such as the industrial aluminum ash is provided in a more recent step.

The aluminum ash has a complex composition and generally contains metallic aluminum, oxides, salt solvents and the like. Therefore, the aluminum ash can be classified into the following two types according to the difference of aluminum content in different aluminum ashes: the aluminum ash with the aluminum content of 15-70 percent is called primary aluminum ash or white aluminum ash, the main components of the aluminum ash are aluminum and oxides thereof, and the aluminum ash is generated in the processes of electrolysis, casting and the like without adding salt flux. The aluminum ash is generated in the process of adding salt flux during the recovery of the aluminum ash, and is called secondary aluminum ash or black aluminum ash. In general, the secondary aluminum ash contains 10-20% of metallic aluminum simple substance, 20-40% of aluminum oxide, 10-20% of aluminum nitride, 7-15% of oxides of silicon, magnesium and iron, 15-30% of sodium, calcium and oxides, partial chloride and a small amount of fluoride. Other components than aluminum are also available and can be recycled by advanced technology.

Therefore, the prior art needs to be improved to realize harmless treatment and full-element resource treatment of secondary aluminum ash.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an efficient secondary aluminum ash harmless and recycling system.

In order to solve the technical problems, the utility model provides a system for harmless treatment and full-element recycling of secondary aluminum ash, which comprises a secondary aluminum ash pretreatment device, a hydrolysis reaction device, a tail gas treatment device, a first filtering device, a stripping deamination device, a first reaction device, a second filtering device, a second reaction device, a third filtering device, a third reaction device, a fourth filtering device, a fourth reaction device, an evaporative crystallization device, a fifth reaction device, a sixth reaction device, a fifth filtering device, a seventh reaction device and a sixth filtering device;

the first reaction device, the second reaction device, the third reaction device, the fourth reaction device, the fifth reaction device, the sixth reaction device and the seventh reaction device are all used for the reaction of secondary aluminum ash;

the first filtering device, the second filtering device, the third filtering device, the fourth filtering device, the fifth filtering device and the sixth filtering device are used for filtering;

the secondary aluminum ash pretreatment device adopts a screening machine, the secondary aluminum ash pretreatment device is conveyed into a closed screening device by a screw conveyor or a gas dry powder conveyor to separate crude aluminum, the crude aluminum can be recycled and sold, waste gas obtained by the screening device is firstly subjected to dust removal, then hydrochloric acid or sulfuric acid is used for absorbing a small amount of ammonia in tail gas, and the tail gas is subjected to dust removal and deamination and then is discharged after reaching standards;

the hydrolysis reaction device is used for two-stage hydrolysis reaction of secondary aluminum ash;

the tail gas treatment device is used for treating tail gas;

the stripping deamination device is used for stripping deamination;

the evaporative crystallization device is used for evaporative crystallization and salt separation.

As an improvement on the system for harmless treatment and full-element recycling of the secondary aluminum ash, the utility model comprises the following steps:

the outlet of the secondary aluminum ash pretreatment device is connected with the inlet of the hydrolysis reaction device;

the gas outlet of the hydrolysis reaction device is connected with the inlet of the tail gas treatment device;

the liquid outlet of the tail gas treatment device is connected with the inlet of the stripping deamination device;

the liquid outlet of the hydrolysis reaction device is connected with the inlet of the first filtering device;

the liquid outlet of the first filtering device is connected with the inlet of the stripping deamination device;

the liquid outlet of the stripping deamination device is respectively connected with the inlet of the first reaction device and the inlet of the seventh reaction device;

the liquid outlet of the first reaction device is connected with the inlet of the second filtering device;

the liquid outlet of the second filtering device is connected with the inlet of the second reaction device;

the liquid outlet of the second reaction device is connected with the inlet of the third filtering device;

the liquid outlet of the third filtering device is connected with the inlet of the third reaction device;

the liquid outlet of the third reaction device is connected with the inlet of the fourth filtering device;

the outlet of the seventh reaction device is connected with the inlet of the sixth filtering device;

the liquid outlet of the fourth filtering device and the liquid outlet of the sixth filtering device are respectively connected with the inlets of the fourth reaction device and the evaporative crystallization device;

the solid outlet of the first filtering device is connected with the inlet of the fifth reaction device;

the liquid outlet of the fifth reaction device is connected with the inlet of the sixth reaction device;

and the liquid outlet of the sixth reaction device is connected with the inlet of the fifth filtering device.

As an improvement on the system for harmless treatment and full-element recycling of the secondary aluminum ash, the utility model comprises the following steps:

adding hydrochloric acid into the first reaction device;

adding hydrochloric acid into the second reaction device;

adding calcium chloride into the third reaction device;

adding liquid caustic soda into the fourth reaction device;

adding hydrochloric acid into the fifth reaction device;

and adding calcium chloride into the seventh reaction device.

The system for harmless treatment and full-element recycling of secondary aluminum ash has the technical advantages that:

1. the method recycles a part of simple substance aluminum in the aluminum ash, converts aluminum nitride nitrogen in the aluminum ash into ammonia and aluminum hydroxide after hydrolysis, recycles the ammonia to prepare 20% ammonia water, and utilizes nitrogen resources in the aluminum ash to the maximum benefit; dissolving sodium, chlorine, partial fluorine, silicate, metaaluminate and the like in the aluminum ash into water in a water washing mode, and respectively recovering silicic acid, calcium fluoride and sodium chloride in different modes to respectively reach the marketable purity meeting the national standard, thereby realizing the recycling of other elements;

2. the aluminum oxide or aluminum hydroxide filter cake after washing is dissolved by hydrochloric acid, and then is cured, cooled and filtered to prepare the polyaluminium chloride which can be used as a water purifying agent, impurities are filtered, the product quality of the polyaluminium chloride is ensured, and the aluminum resource in the aluminum ash is utilized to the maximum extent;

3. if the tail gas of the system is dust, the dust is removed, then ammonia is absorbed and recovered by water, and then the ammonia generated in the production process is recovered by hydrochloric acid, so that the waste gas is ensured to be discharged after reaching the standard; the wastewater after deamination, defluorination and impurity removal can be discharged after reaching the standard, and sodium chloride products meeting the national standard can be obtained for sale in an evaporative crystallization mode, so that zero discharge of the wastewater is realized. The waste water and the waste gas of the system can be discharged up to the standard, and the elements such as aluminum, nitrogen, sodium, chlorine, fluorine, water and the like in the secondary aluminum ash are separated and purified, so that the harmlessness, the recycling and the productization are realized, the full-element recycling of the secondary aluminum ash is realized, and the system has better social and economic benefits.

Drawings

The following describes embodiments of the present invention in further detail with reference to the accompanying drawings.

FIG. 1 is a schematic block diagram of a system for harmless treatment and full-element recycling of secondary aluminum ash according to the present invention.

Detailed Description

The utility model will be further described with reference to specific examples, but the scope of the utility model is not limited thereto.

Embodiment 1, a system for secondary aluminum ash harmless and full element resource utilization, as shown in fig. 1, includes a secondary aluminum ash pretreatment device 1, a hydrolysis reaction device 2, a tail gas treatment device 3, a first filter device 4, a stripping deamination device 5, a first reaction device 6, a second filter device 7, a second reaction device 8, a third filter device 9, a third reaction device 10, a fourth filter device 11, a fourth reaction device 12, an evaporative crystallization device 13, a fifth reaction device 14, a sixth reaction device 15, a fifth filter device 16, a seventh reaction device 17 and a sixth filter device 18.

The outlet of the secondary aluminum ash pretreatment device 1 is connected with the inlet of the hydrolysis reaction device 2;

the gas outlet of the hydrolysis reaction device 2 is connected with the inlet of the tail gas treatment device 3;

the liquid outlet of the tail gas treatment device 3 is connected with the inlet of the stripping deamination device 5;

the liquid outlet of the hydrolysis reaction device 2 is connected with the inlet of the first filtering device 4;

the liquid outlet of the first filtering device 4 is connected with the inlet of the stripping deamination device 5;

a liquid outlet of the stripping deamination device 5 is respectively connected with an inlet of the first reaction device 6 and an inlet of the seventh reaction device 17;

the liquid outlet of the first reaction device 6 is connected with the inlet of the second filtering device 7;

the liquid outlet of the second filtering device 7 is connected with the inlet of the second reaction device 8;

the liquid outlet of the second reaction device 8 is connected with the inlet of a third filtering device 9;

the liquid outlet of the third filtering device 9 is connected with the inlet of the third reaction device 10;

the liquid outlet of the third reaction device 10 is connected with the inlet of a fourth filtering device 11;

the outlet of the seventh reaction device 17 is connected with the inlet of a sixth filtering device 18;

the liquid outlet of the fourth filtering device 11 and the liquid outlet of the sixth filtering device 18 are respectively connected with the inlets of the fourth reaction device 12 and the evaporative crystallization device 13;

the solid outlet of the first filtering device 4 is connected with the inlet of the fifth reaction device 14;

the liquid outlet of the fifth reaction device 14 is connected with the inlet of the sixth reaction device 15;

the liquid outlet of the sixth reaction device 15 is connected with the inlet of the fifth filtering device 16.

The first reaction device 6, the second reaction device 8, the third reaction device 10, the fourth reaction device 12, the fifth reaction device 14, the sixth reaction device 15 and the seventh reaction device 17 are all used for secondary aluminum ash reaction; adding hydrochloric acid into a first reaction device 6, adding hydrochloric acid into a second reaction device 8, adding calcium chloride into a third reaction device 10, adding liquid caustic soda into a fourth reaction device 12, adding hydrochloric acid into a fifth reaction device 14, and adding calcium chloride into a seventh reaction device 17;

the first filtering device 4, the second filtering device 7, the third filtering device 9, the fourth filtering device 11, the fifth filtering device 16 and the sixth filtering device 18 are used for filtering;

the secondary aluminum ash pretreatment device 1 adopts a sieving machine, a screw conveyor or a gas dry powder conveyor is used for conveying the coarse aluminum into a closed sieving device for separating the coarse aluminum, the coarse aluminum can be recycled and sold, the waste gas obtained by the sieving device is firstly dedusted, then hydrochloric acid or sulfuric acid is used for absorbing a small amount of ammonia in the tail gas, and the tail gas is dedusted and deaminated and then is discharged after reaching the standard.

The hydrolysis reaction device 2 is used for two-stage hydrolysis reaction of secondary aluminum ash;

the tail gas treatment device 3 is used for treating tail gas;

the stripping deamination device 5 is used for stripping deamination;

the evaporative crystallization device 13 is used for evaporative crystallization and salt separation.

The utility model relates to a secondary aluminum ash harmless and recycling process, which comprises the following steps:

step one, adding the secondary aluminum ash into a secondary aluminum ash pretreatment device 1 for pretreatment to obtain screened aluminum ash.

The secondary aluminum ash pretreatment device 1 can adopt a sieving machine, a screw conveyor or a gas dry powder conveyor is used for conveying the coarse aluminum into a closed sieving device for separating the coarse aluminum, the coarse aluminum can be recycled and sold, the waste gas obtained by the sieving device is firstly dedusted, hydrochloric acid or sulfuric acid is used for absorbing a small amount of ammonia in the tail gas, and the tail gas is dedusted and deaminated and then is discharged after reaching the standard.

And step two, adding the screened aluminum ash into a hydrolysis reaction device 2, adding water (the mass ratio of the screened aluminum ash to the water is 1: 1-15) for reaction to obtain waste gas and slurry after hydrolysis reaction, wherein the slurry mainly comprises alumina, aluminum hydroxide, ammonia, sodium chloride and a small amount of impurities such as calcium fluoride, calcium sulfate, sodium metaaluminate, sodium fluoride, sodium sulfate and the like.

The reaction may be carried out using two stages of hydrolysis:

the first stage of reaction at normal temperature and pressure, most of salt is dissolved in water, and a small amount of ALN is decomposed into AL (OH)₃Reacting with ammonia for 1 hour (0.1-3 hours), and hydrolyzing to perform the following reaction:

Na₂O+H₂O——>2NaOH

Al₂O₃+3H₂O——>2Al(OH)₃

2NaOH+SiO₂——>Na₂SiO₃+H₂O

2NaOH+Al₂O₃——>2NaAlO₂+H₂O

the second-stage reaction is carried out under the conditions of heating (80-100 ℃) and pressurization (0.1-1.0MPa) in a sealed manner for hydrolysis reaction, the reaction time is 0.5-5 hours, most ALN is subjected to hydrolysis reaction, and the reaction formula is as follows:

ALN+3H₂O——>AL(OH)₃↓+NH₃↑

adding the reacted waste gas into a tail gas treatment device 3, treating the tail gas in two stages, firstly absorbing ammonia in the tail gas by using water, then absorbing residual ammonia in the tail gas by using hydrochloric acid (or dilute sulfuric acid), discharging the tail gas up to the standard, obtaining an absorption waste liquid by the tail gas treatment device 3, wherein the main components of the waste liquid are ammonia, ammonia chloride and water.

The water is recycled in the water absorption process, the feeding and discharging of the water are controlled, and the pH value of the absorption liquid is not more than 10;

the hydrochloric acid or dilute sulfuric acid absorption liquid is recycled, and the addition amount of the hydrochloric acid and the discharge amount of waste liquid are controlled, so that the pH value of the hydrochloric acid absorption liquid is not more than 4, and the tail gas is ensured to be discharged after reaching the standard;

and step three, adding the slurry reacted by the hydrolysis reaction device 2 into a first filtering device 4 for filtering, washing a filtered filter cake with clear water, wherein the washed filter cake is almost free of peculiar smell.

And step four, mixing the filtrate filtered by the first filtering device 4, the washing liquid and the absorption waste liquid treated by the tail gas treatment device 3 (if the pH is less than 12 after mixing, adding liquid caustic soda to adjust the pH to be more than or equal to 12), adding the mixture into a stripping deamination device 5 for stripping deamination, recycling ammonia in the waste water to prepare 20% ammonia water for sale, and obtaining the deaminated waste water, wherein the ammonia in the waste water is less than 10 mg/L.

Step five: removing impurities from the deaminated wastewater, and respectively removing silicate, metaaluminate, fluoride ions and sulfate radicals in the wastewater by adopting one of the following two paths:

path one: adding the deaminated wastewater into a first reaction device 6, adding hydrochloric acid, and adjusting the pH to 5.5-7.5; wherein, the sodium metaaluminate reacts with hydrochloric acid to separate out aluminum hydroxide solid, and the reaction formula is as follows:

NaALO₂+HCL+H₂O——>NaCL+AL(OH)₃↓

then filter through second filter equipment 7, second reaction unit 8 is added to the filtrating after second filter equipment 7 filters, then adds hydrochloric acid, adjusts pH to 2 ~ 5, and wherein a small amount of sodium silicate separates out silicic acid after reacting with hydrochloric acid, and the reaction formula is:

Na₂SiO3+2HCl——>2NaCl+H2SiO3↓

filtering in a third filtering device 9 after reaction, wherein the main component of a filter cake is silicic acid, and the main components of filtrate are sodium chloride and sodium fluoride;

adding the filtrate filtered by the third filtering device 9 into a third reaction device 10, adding a calcium hydroxide solution with the mass concentration of 5-50%, reacting sodium fluoride in the wastewater with calcium chloride to generate sodium chloride and calcium fluoride precipitates, reacting sodium sulfate in the wastewater with calcium chloride to generate calcium sulfate dihydrate precipitates, and adding calcium chloride until no precipitate is generated, wherein the specific reaction formula is as follows:

2NaF+CaCL₂——>CaF₂↓+2NaCL

Na₂SO4+CaCL₂+2H₂O——>CASO₄·2H₂O↓+NaCL

then filtering in a fourth filtering device 11, wherein a filter cake is a mixture of calcium fluoride and calcium sulfate dihydrate, and the content of fluoride ions in a filtrate is less than 10 mg/L;

and a second route:

mixing the deaminated wastewater with a calcium chloride solution with the mass concentration of 5-50% in a seventh reaction device 17 for reaction, wherein the following reaction occurs:

2NaALO₂+CaCl₂——>Ca(AlO2)₂↓+2NaCl

Na₂SiO3+CaCl₂——>CaSiO3↓+2NaCl

2NaF+CaCL₂——>CaF₂↓+2NaCL

Na₂SO4+CaCL₂+2H₂O——>CASO₄·2H₂O↓+NaCL

the reaction of the calcium ions and the metatchlorate, the fluoride ions, the silicic acid radicals and the sulfate radicals in the wastewater generates precipitates, and then a filter cake filtered by the sixth filtering device 18 is used as a cement raw material for treatment;

the filtrate filtered by the sixth filtering device 11 or the sixth filtering device 18 in the sixth step adopts one of the following two schemes according to actual situations:

the method comprises the steps of adding the wastewater into a fourth reaction device 12, adding liquid caustic soda to adjust the pH to be neutral (the pH is 6.0-9.0), wherein the ammonia in the wastewater is lower than 10mg/L, and the fluorine ion is lower than 10mg/L, so that the wastewater can reach the standard and be discharged;

and the second scheme is that the sodium chloride is added into an evaporative crystallization device 13 for evaporative crystallization, then centrifugal filtration is carried out to respectively obtain sodium chloride and steam condensate, the sodium chloride solid is sold, and the steam condensate returns to the hydrolysis reaction device 2 to participate in the hydrolysis reaction.

And step seven, adding a filter cake obtained by filtering in the first filtering device 4 into the fifth reaction device 14, adding hydrochloric acid (or dilute sulfuric acid can be used for replacing the hydrochloric acid), and carrying out acid dissolution reaction at normal pressure and normal temperature for about 2 hours (the range is 1-5 hours) to obtain a reactant of the acid dissolution reaction.

The mass concentration of the hydrochloric acid is 10 percent (the mass concentration is 5 to 31 percent); the mass concentration of the dilute sulfuric acid is 2-50%.

Adding the reactant of the acid-soluble reaction into a sixth reaction device 15, and carrying out an aging reaction at a temperature of 70 ℃ (in the range of 60-90 ℃), wherein the aging time is about 2 hours (in the range of 1-5 hours);

and cooling the reactant of the curing reaction to normal temperature, adding the cooled reactant into a fifth filtering device 16, filtering to remove solid impurities such as calcium fluoride, ferric oxide and the like, and obtaining colorless or light-colored transparent liquid, namely the crude product of the polyaluminium chloride.

The filter cake obtained by filtering the first filtering device 4 can be used as a cement brick or can be sold as a cement raw material.

Finally, it is also noted that the above-mentioned lists merely illustrate a few specific embodiments of the utility model. It is obvious that the utility model is not limited to the above embodiments, but that many variations are possible. All modifications which can be derived or suggested by a person skilled in the art from the disclosure of the present invention are to be considered within the scope of the utility model.

Claims (3)

1. The utility model provides a system that secondary aluminium ash is innoxious and full element resourceization which characterized in that: the device comprises a secondary aluminum ash pretreatment device (1), a hydrolysis reaction device (2), a tail gas treatment device (3), a first filtering device (4), a stripping deamination device (5), a first reaction device (6), a second filtering device (7), a second reaction device (8), a third filtering device (9), a third reaction device (10), a fourth filtering device (11), a fourth reaction device (12), an evaporation crystallization device (13), a fifth reaction device (14), a sixth reaction device (15), a fifth filtering device (16), a seventh reaction device (17) and a sixth filtering device (18);

the outlet of the secondary aluminum ash pretreatment device (1) is connected with the inlet of the hydrolysis reaction device (2);

the gas outlet of the hydrolysis reaction device (2) is connected with the inlet of the tail gas treatment device (3);

the liquid outlet of the tail gas treatment device (3) is connected with the inlet of the stripping deamination device (5);

the liquid outlet of the hydrolysis reaction device (2) is connected with the inlet of the first filtering device (4);

the liquid outlet of the first filtering device (4) is connected with the inlet of a stripping deamination device (5);

the liquid outlet of the stripping deamination device (5) is respectively connected with the inlet of the first reaction device (6) and the inlet of the seventh reaction device (17);

the liquid outlet of the first reaction device (6) is connected with the inlet of the second filtering device (7);

the liquid outlet of the second filtering device (7) is connected with the inlet of the second reaction device (8);

the liquid outlet of the second reaction device (8) is connected with the inlet of a third filtering device (9);

the liquid outlet of the third filtering device (9) is connected with the inlet of a third reaction device (10);

the liquid outlet of the third reaction device (10) is connected with the inlet of a fourth filtering device (11);

the outlet of the seventh reaction device (17) is connected with the inlet of a sixth filtering device (18);

the liquid outlet of the fourth filtering device (11) and the liquid outlet of the sixth filtering device (18) are respectively connected with the inlets of the fourth reaction device (12) and the evaporative crystallization device (13);

the solid outlet of the first filtering device (4) is connected with the inlet of a fifth reaction device (14);

the liquid outlet of the fifth reaction device (14) is connected with the inlet of the sixth reaction device (15);

and the liquid outlet of the sixth reaction device (15) is connected with the inlet of a fifth filtering device (16).

2. The system for harmless and full-element resource utilization of secondary aluminum ash as claimed in claim 1, wherein:

the first reaction device (6), the second reaction device (8), the third reaction device (10), the fourth reaction device (12), the fifth reaction device (14), the sixth reaction device (15) and the seventh reaction device (17) are all used for reacting secondary aluminum ash;

the first filtering device (4), the second filtering device (7), the third filtering device (9), the fourth filtering device (11), the fifth filtering device (16) and the sixth filtering device (18) are used for filtering;

the secondary aluminum ash pretreatment device (1) adopts a screening machine, a screw conveyor or a gas dry powder conveyor is used for conveying the secondary aluminum ash into a closed screening device to separate crude aluminum, the crude aluminum can be recycled and sold, waste gas obtained by the screening device is firstly subjected to dust removal, hydrochloric acid or sulfuric acid is then used for absorbing a small amount of ammonia in tail gas, and the tail gas is subjected to dust removal and deamination and then is discharged after reaching standards;

the hydrolysis reaction device (2) is used for two-stage hydrolysis reaction of secondary aluminum ash;

the tail gas treatment device (3) is used for treating tail gas;

the stripping deamination device (5) is used for stripping deamination;

the evaporative crystallization device (13) is used for evaporative crystallization and salt separation.

3. The system for harmless and full-element resource utilization of secondary aluminum ash as claimed in claim 2, wherein:

hydrochloric acid is added into the first reaction device (6);

hydrochloric acid is added into the second reaction device (8);

calcium chloride is added into the third reaction device (10);

adding liquid caustic soda into the fourth reaction device (12);

hydrochloric acid is added into the fifth reaction device (14);

and calcium chloride is added into the seventh reaction device (17).

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