WO2018233687A1 - 钙铁榴石一步碱热法处理中低品位铝土矿生产铝酸钠的方法 - Google Patents

钙铁榴石一步碱热法处理中低品位铝土矿生产铝酸钠的方法 Download PDF

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WO2018233687A1
WO2018233687A1 PCT/CN2018/092423 CN2018092423W WO2018233687A1 WO 2018233687 A1 WO2018233687 A1 WO 2018233687A1 CN 2018092423 W CN2018092423 W CN 2018092423W WO 2018233687 A1 WO2018233687 A1 WO 2018233687A1
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sodium aluminate
medium
grade bauxite
thermal treatment
calcium
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PCT/CN2018/092423
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French (fr)
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潘晓林
于海燕
吴艳
毕诗文
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东北大学
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    • CCHEMISTRY; METALLURGY
    • C01INORGANIC CHEMISTRY
    • C01FCOMPOUNDS OF THE METALS BERYLLIUM, MAGNESIUM, ALUMINIUM, CALCIUM, STRONTIUM, BARIUM, RADIUM, THORIUM, OR OF THE RARE-EARTH METALS
    • C01F7/00Compounds of aluminium
    • C01F7/02Aluminium oxide; Aluminium hydroxide; Aluminates
    • C01F7/04Preparation of alkali metal aluminates; Aluminium oxide or hydroxide therefrom

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  • the invention belongs to the technical field of sodium aluminate production, and particularly relates to a method for producing sodium aluminate in low-grade bauxite by a one-step alkali heat treatment of calcium iron garnet.
  • the low-grade bauxite treatment methods mainly include the Bayer method, the sintering method, and the Bayer-sintering method.
  • the enhanced Bayer method is a method based on the Bayer method to improve the treatment of medium and low grade bauxite, mainly including the beneficiation Bayer method and the lime Bayer method.
  • the beneficiation Bayer method uses the combination of smelting and smelting to treat medium and low grade bauxite.
  • the process is relatively simple, but there are problems such as difficulty in physical beneficiation, large consumption of raw ore, low recovery rate of alumina, and influence of Bayer process by flotation reagents.
  • the lime Bayer method is based on the Bayer process, and the effect of reducing alkali consumption is achieved by adding excess lime, but the amount of lime added is large.
  • the problem is that the dissolution rate of alumina is greatly reduced, the amount of red mud discharge is increased, and the red mud sedimentation load is increased.
  • the sintering method mainly includes the soda lime sintering method and the lime sintering method, but the high energy consumption and high production cost are the main shortcomings of the development.
  • the soda lime sintering method belongs to wet compounding and wet sintering.
  • Bayer-sintering combined method includes series method, parallel method and hybrid method, which can deal with medium and low grade bauxite, but it has complicated problems and high energy consumption. It has been basically replaced by Bayer method.
  • Other processes such as acid method and acid-base combination method mainly stay in the laboratory research stage, and there are many problems such as poor quality of alumina products and serious corrosion of equipment.
  • the present invention aims to provide a method for producing sodium aluminate in a low-grade bauxite by a one-step alkali thermal treatment of calcium iron garnet, which is added in a high-temperature dissolution process by a one-step alkali heat method.
  • a method for producing sodium aluminate in a low-grade bauxite by a one-step alkali thermal treatment of calcium iron garnet which is added in a high-temperature dissolution process by a one-step alkali heat method.
  • aluminum enters the solution in the form of sodium aluminate during high temperature dissolution, and silicon remains in the dissolution slag in the form of calcium iron garnet.
  • the method of the invention can greatly improve the dissolution rate of alumina, has the characteristics of short process and high efficiency, and realizes zero discharge of materials in the whole process.
  • the main technical solutions adopted by the present invention include:
  • a method for treating sodium aluminate in low-grade bauxite by a one-step alkali heat treatment of calcium iron garnet comprising the following steps:
  • the polymer is prepared by a sodium aluminate solution to prepare a circulating mother liquid used in the step S2.
  • the total amount of iron, aluminum, calcium and silicon present in each form is respectively determined by the oxide, and the formulation formula is as follows:
  • the mass ratio of the total amount of iron oxide to the total amount of alumina is 0.2 to 0.6:1;
  • the molar ratio of the total amount of calcium oxide to the total amount of iron oxide is from 3 to 6:1.
  • the raw material slurry has a liquid to solid ratio of 2 to 5:1.
  • the polymer is prepared by reacting a caustic alkali concentration with a sodium aluminate solution to obtain a circulating mother liquor, wherein the concentration of the caustic in the circulating mother liquor is 150 to 250 g/L, and the molecular ratio is 5 to 25.
  • the temperature of the dissolution reaction in the step S3 is 150 to 250 ° C, and the reaction time is 0.5 to 2 h.
  • the method further includes:
  • Step S7 washing the eluted slag in step S4 and solid-liquid separation to obtain calcium garnet type red mud and washing liquid;
  • Step S8 The washing liquid is used to dilute the dissolved slurry in step S4.
  • step S5 specifically includes the following steps:
  • S51 adding a seed crystal to the evaporated sodium aluminate solution to perform crystallization to obtain a crystal slurry
  • S52 performing liquid-solid separation on the crystal slurry to obtain a polymer ratio sodium aluminate solution and sodium aluminate.
  • the crystallization temperature in the step S51 is 85 to 40 ° C
  • the crystallization time is 10 to 30 h
  • the seed crystal addition amount is 10 to 200 g/L.
  • the sodium ferrite in step S1 is formed by sintering an iron-containing raw material and an industrial carbon base.
  • the method of the present invention produces a red mud base content of 0.5% or less
  • the method of the invention has the characteristics of short process and high efficiency, and the whole process is green and environmentally friendly;
  • the product sodium aluminate can be used as a raw material to prepare other aluminum-containing products, and can also be used as a raw material to prepare metallurgical grade alumina by a simple Bayer process.
  • FIG. 1 is a process flow diagram of a method for producing sodium aluminate in a low-grade bauxite by a one-step alkali thermal treatment of calcium iron garnet according to the present invention.
  • the ratio of silicon to aluminum (hereinafter referred to as A/S) is 2-6, and the total iron oxide and total alumina in the raw material ore composed of bauxite, sodium ferrite and lime.
  • the mass ratio is abbreviated as F/A; the molar ratio of total calcium oxide to total iron oxide is hereinafter abbreviated as C/F; the raw material slurry solid mass ratio is abbreviated as L/S.
  • Calcium iron garnet one-step alkali heat treatment of low-grade bauxite to produce sodium aluminate means that the dissolved slag is calcium iron garnet type slag, and the one-step alkali heat method refers to the use of lye (circulating mother liquor) to alumina.
  • a one-step hydrothermal dissolution treatment is carried out, and the target product produced is sodium aluminate.
  • the medium and low grade bauxite used in this embodiment has the main chemical composition (mass percentage, wt%): alumina (Al 2 O 3 ) 60.60%, silica (SiO 2 ) 17.5%, others are impurities, Aluminum to silicon ratio is 3.5;
  • Sodium ferrite is sintered from iron-containing raw materials and industrial caustic soda
  • the concentration of caustic in the circulating mother liquor is 200 g / L, the molecular ratio is 25;
  • the extraction rate of alumina can reach 83.5%
  • the concentration of the caustic alkali and the molecular ratio in the sodium aluminate solution need to be adjusted to meet the parameter requirements of the circulating mother liquor, and used to prepare the raw material slurry and carry out the dissolution reaction;
  • step S7 washing the slag in step S4 and solid-liquid separation to obtain calcium garnet type slag and washing liquid;
  • the low alkali calcium iron garnet type slag is obtained after treatment, and the silicon and the added iron and calcium remain in the dissolution slag in the form of calcium iron garnet, thereby reducing the alkali content in the dissolution slag;
  • step S8 using the washing liquid to dilute the dissolved ore slurry in step S4;
  • the generated washing liquid is returned to the step S4 for diluting the dissolved ore slurry, which not only reduces the treatment and discharge of the waste liquid, but also achieves the recycling and reuse of the material.
  • the obtained sodium aluminate is a product.
  • the medium and low grade bauxite used in this embodiment has the main chemical composition (mass percentage, wt%): alumina (Al 2 O 3 ) 65.22%, silica (SiO 2 ) 12.66%, and others are impurities.
  • the ratio of aluminum to silicon is 5.15;
  • Sodium ferrite is sintered from iron-containing raw materials and industrial sodium carbonate
  • the concentration of caustic in the circulating mother liquor was 250 g/L and the molecular ratio was 20.
  • the extraction rate of alumina can reach 83.7%
  • the caustic concentration and the molecular ratio in the sodium aluminate solution need to be adjusted to meet the parameter requirements of the circulating mother liquor, and used to prepare the raw material slurry and carry out the dissolution reaction;
  • step S7 washing the slag in step S4 and solid-liquid separation to obtain calcium garnet type slag and washing liquid;
  • the low alkali calcium iron garnet type slag is obtained after treatment, and the silicon and the added iron and calcium remain in the dissolution slag in the form of calcium iron garnet, thereby reducing the alkali content in the dissolution slag;
  • step S8 using the washing liquid to dilute the dissolved ore slurry in step S4;
  • the generated washing liquid is returned to the step S4 for diluting the dissolved ore slurry, which not only reduces the treatment and discharge of the waste liquid, but also achieves the recycling and reuse of the material.
  • the obtained sodium aluminate is a product.
  • the method of the invention has the characteristics of short process and high efficiency, and the material realizes zero discharge in the whole process.
  • fly ash can also be used to produce sodium aluminate by the method of the invention, and in the furnish, the fly ash can be directly applied without being subjected to crushing and grinding treatment, so that the method of the invention has a shorter process. higher efficiency.

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  • Compounds Of Alkaline-Earth Elements, Aluminum Or Rare-Earth Metals (AREA)

Abstract

提供一种钙铁榴石一步碱热法处理中低品位铝土矿生产铝酸钠的方法,包括下述步骤,S1:将中低品位铝土矿破碎磨细成矿粉;S2:将矿粉、铁酸钠、活性石灰和循环母液混合制备成原料矿浆;S3:将原料矿浆进行碱热溶出反应;S4:将溶出矿浆稀释并将稀释液进行液固分离,得到铝酸钠溶液和溶出渣;S5:将铝酸钠溶液蒸发后加晶种结晶并固液分离,得到铝酸钠固体和高分子比铝酸钠溶液;S6:将高分子比铝酸钠溶液进行调制,制成循环母液。该方法采用碱热溶出,通过在溶出过程中添加石灰和铁酸钠,使溶出中生成理论上不含碱的钙铁榴石型渣,能够大幅度提高氧化铝的溶出率,具有流程短、效率高的特点,整个流程中物料实现了零排放。

Description

钙铁榴石一步碱热法处理中低品位铝土矿生产铝酸钠的方法 技术领域
本发明属于铝酸钠生产的技术领域,具体涉及一种钙铁榴石一步碱热法处理中低品位铝土矿生产铝酸钠的方法。
背景技术
现有铝土矿资源绝大多数为中低品位铝土矿,具有高铝,高硅,低铝硅比(A/S)等特点,硅铝比(以下简称A/S)一般为2~6。随着矿石品位的降低,各氧化铝生产工艺成本均在逐渐增加,其中拜耳法工艺增幅最大。根据拜耳法的基本工艺和原理,当铝土矿A/S下降到5以下时,将很难再用拜耳法处理。针对于低品位铝土矿,近年来氧化铝工业界主要采用如下几种方法:
如中低品位铝土矿处理方法主要有强化拜耳法、烧结法、拜耳-烧结联合法等。强化拜耳法是在拜耳法基础上,进行改进以适应处理中低品位铝土矿的方法,主要包括选矿拜耳法和石灰拜耳法。其中,选矿拜耳法采用选冶联合处理中低品位铝土矿,流程相对简单,但存在物理选矿难度大、原矿消耗量大、氧化铝回收率低、浮选药剂影响拜耳法流程等问题,同时选矿过程产生大量铝硅比低于2的尾矿无法利用,造成资源的极大浪费;石灰拜耳法是在拜耳法基础上,通过添加过量石灰以达到降低碱耗等作用,但石灰添加量大导致氧化铝溶出率大幅降低、赤泥排出量增加、赤泥沉降负荷增大等问题。烧结法主要包括碱石灰烧结法和石灰烧结法,但能耗高、生产成本高是其发展的主要短板。碱石灰烧结法属于湿法配料、湿法烧结,在烧结过程生料浆中40%左右的水分蒸发极大增加了生产总能耗,且烧结熟料中2CaO·SiO 2稳定性较低,二次反应严重;石灰烧结法存在石灰配比高、弃渣量大、熟料氧化铝浸出率低 等问题。拜耳-烧结联合法包括串联法、并联法和混联法,能够处理中低品位铝土矿,但存在流程复杂、能耗高等问题,目前已基本被拜耳法所取代。其它如酸法和酸碱联合法等工艺目前主要停留在实验室研究阶段,存在氧化铝产品质量差、设备腐蚀严重等诸多问题。
纵观以上处理中低品位铝土矿的方法,烧结法和拜耳-烧结联合法由于其能耗和成本问题已基本被弃用,石灰拜耳法是特定历史时期为解决碱耗问题而研发的,目前只有选矿拜耳法在中国铝业中州分公司应用。然而,经过近些年的工业实践,选矿拜耳法日益暴露出的问题已经严重阻碍了生产过程的正常运行,成为其继续推广发展的瓶颈。
发明内容
(一)要解决的技术问题
为了解决现有技术的上述问题,本发明目的在于提供一种钙铁榴石一步碱热法处理中低品位铝土矿生产铝酸钠的方法,利用一步碱热法,在高温溶出过程中添加铁酸钠及活性石灰的方法,高温溶出过程中铝以铝酸钠形式进入溶液,而硅以钙铁榴石的形式留在溶出渣中。本发明的方法能够大幅度提高氧化铝的溶出率,具有流程短、效率高的特点,整个流程中物料实现了零排放。
(二)技术方案
为了达到上述目的,本发明采用的主要技术方案包括:
一种钙铁榴石一步碱热法处理中低品位铝土矿生产铝酸钠的方法,包括下述步骤,
S1:将中低品位铝土矿破碎磨细成矿粉;
S2:将矿粉、铁酸钠、活性石灰和循环母液混合制备成原料矿浆;
S3:将原料矿浆进行碱热溶出反应,反应结束后得到溶出矿浆;
S4:将溶出矿浆稀释得到稀释液,将稀释液进行液固分离,得到溶出渣和溶出液,其中溶出液为铝酸钠溶液;
S5:将铝酸钠溶液蒸发后加晶种结晶并固液分离,得到铝酸钠和高 分子比铝酸钠溶液;
S6:将所述高分子比铝酸钠溶液进行调制,制成步骤S2中所用的循环母液。
优选地,在赤泥、铁酸钠、活性石灰组成的原料矿浆中,各形态存在的铁、铝、钙、硅总量分别以氧化物计,配料配方如下:
氧化铁的总量与氧化铝的总量的质量比为0.2~0.6∶1;
氧化钙的总量与氧化铁的总量的摩尔比为3~6∶1。
优选地,所述原料矿浆的液固比为2~5∶1。
优选地,步骤S6中所述高分子比铝酸钠溶液进行苛碱浓度调制后得到循环母液,其中,循环母液中的苛碱浓度为150~250g/L,分子比为5~25。
优选地,步骤S3中溶出反应的温度为150~250℃,反应时间为0.5~2h。
优选地,所述方法还包括:
步骤S7:将步骤S4中的溶出渣进行洗涤并固液分离,得到钙铁榴石型赤泥和洗涤液;
步骤S8:将所述洗涤液用于步骤S4中稀释所述溶出矿浆。
优选地,步骤S5具体包括下述步骤:
S51:将晶种加入到蒸发后的铝酸钠溶液进行结晶,得到结晶浆料;S52:将结晶浆料进行液固分离,得到高分子比铝酸钠溶液和铝酸钠。
优选地,步骤S51中的结晶温度为85~40℃,结晶时间为10~30h,晶种添加量为10~200g/L。
优选地,步骤S1中的铁酸钠是含铁原料与工业碳碱烧结而成。
(三)有益效果
本发明的有益效果是:
(1)与常规拜耳法相比,本发明的方法氧化铝实际溶出率提高了15%以上,大幅度地提高了氧化铝的溶出率;
(2)与常规拜耳法相比,本发明的方法产生的赤泥碱含量在0.5% 以下;
(3)本发明的方法具有流程短、效率高的特点,整个流程绿色环保;
(4)产品铝酸钠即可单独做试剂用来制备其他含铝产品,也可作为原料通过简单的拜耳法制备冶金级氧化铝。
附图说明
图1为本发明钙铁榴石一步碱热法处理中低品位铝土矿生产铝酸钠方法的工艺流程图。
具体实施方式
下面结合具体实施例,进一步阐述本发明。应理解,这些实施例仅用于说明本发明,而不用于限制本发明的范围。
本发明实施例中的中低品位铝土矿,硅铝比(以下简称A/S)为2~6,铝土矿、铁酸钠和石灰组成的原料矿中,总氧化铁与总氧化铝的质量比以下简写为F/A;总氧化钙与总氧化铁的摩尔比以下简写为C/F;原料矿浆液固质量比以下简写为L/S。
钙铁榴石一步碱热法处理中低品位铝土矿生产铝酸钠的方法,是指溶出渣为钙铁榴石型渣,一步碱热法是指利用碱液(循环母液)对氧化铝进行一步水热溶出处理的方法,生产的目标产品为铝酸钠。
实施例1
本实施例采用的中低品位铝土矿,主要化学成分(质量百分比,wt%)为:氧化铝(Al 2O 3)  60.60%,二氧化硅(SiO 2)  17.5%,其它为杂质,其铝硅比为3.5;
铁酸钠为含铁原料与工业烧碱烧结而成;
循环母液中的苛碱浓度为200g/L,分子比为25;
F/A=0.5∶1;
C/F=4.5∶1。
按照如图1所示的本发明钙铁榴石一步碱热法处理中低品位铝土矿生产铝酸钠的方法:
S1:将中低品位铝土矿破碎磨细成矿粉;
S2:将矿粉、铁酸钠、活性石灰混合后,按照L/S=4∶1的比例与循环母液混合制备成原料矿浆;
S3:将原料矿浆在反应釜中进行溶出反应,溶出反应温度为250℃,溶出反应时间为2h,反应结束后得到溶出矿浆;
经过本步骤的溶出反应处理,氧化铝的提取率能够达到83.5%;
S4:将溶出矿浆稀释得到稀释液,将稀释液进行液固分离,得到溶出渣和溶出液,其中溶出液为铝酸钠溶液;
S51:将10g/L晶种加入到蒸发浓缩后的低分子比铝酸钠溶液在85~40℃进行结晶15h,得到结晶浆料;
S52:将结晶浆料进行液固分离,得到高分子比铝酸钠溶液和铝酸钠固体;
S6:将高分子比铝酸钠溶液进行调制,制成步骤S2中所用的循环母液;
本步骤中高分子比铝酸钠溶液中的苛碱浓度及分子比均需调整以达到循环母液的参数要求,用于配制原料浆并进行溶出反应;
S7:将步骤S4中的溶出渣进行洗涤并固液分离,得到钙铁榴石型渣和洗涤液;
本步骤中,经过处理得到了低碱的钙铁榴石型渣,硅与加入的铁和钙以钙铁榴石的形式留在溶出渣中,降低了溶出渣中的碱含量;
S8:将所述洗涤液用于步骤S4中稀释所述溶出矿浆;
产生的洗涤液返回到步骤S4中用于稀释溶出矿浆,既减少了废液的处理和排放,又达到了物料的回收再利用。
得到的铝酸钠即为产品。
实施例2
本实施例采用的中低品位铝土矿,主要化学成分(质量百分比,wt%)为:氧化铝(Al 2O 3)  65.22%,二氧化硅(SiO 2)  12.66%,其它为杂 质,其铝硅比为5.15;
铁酸钠为含铁原料与工业碳酸钠烧结而成;
循环母液中的苛碱浓度为250g/L,分子比为20。
F/A=0.6∶1;
C/F=4∶1。
按照如图1所示的本发明钙铁榴石一步碱热法处理中低品位铝土矿生产铝酸钠的方法:
S1:将中低品位铝土矿破碎磨细成矿粉;
S2:将矿粉、铁酸钠、活性石灰混合后,按照L/S=4∶1的比例与循环母液混合制备成原料矿浆;
S3:将原料矿浆在反应釜中进行溶出反应,溶出反应温度为250℃,溶出反应时间为2h,反应结束后得到溶出矿浆;
经过本步骤的溶出反应处理,氧化铝的提取率能够达到83.7%;
S4:将溶出矿浆稀释得到稀释液,将稀释液进行液固分离,得到溶出渣和溶出液,其中溶出液为低分子比铝酸钠溶液;
S51:将150g/L晶种加入到蒸发浓缩后的低分子比铝酸钠溶液在85~40℃进行蒸发结晶10h,得到结晶浆料;
S52:将结晶浆料进行液固分离,得到高分子比铝酸钠溶液和固体铝酸钠;
S6:将高分子比铝酸钠溶液进行调制,制成步骤S2中所用的循环母液;
本步骤中铝酸钠溶液中的苛碱浓度及分子比均需调整以达到循环母液的参数要求,用于配制原料浆并进行溶出反应;
S7:将步骤S4中的溶出渣进行洗涤并固液分离,得到钙铁榴石型渣和洗涤液;
本步骤中,经过处理得到了低碱的钙铁榴石型渣,硅与加入的铁和钙以钙铁榴石的形式留在溶出渣中,降低了溶出渣中的碱含量;
S8:将所述洗涤液用于步骤S4中稀释所述溶出矿浆;
产生的洗涤液返回到步骤S4中用于稀释溶出矿浆,既减少了废液的处理和排放,又达到了物料的回收再利用。
得到的铝酸钠即为产品。
本发明的方法具有流程短、效率高的特点,整个流程中物料实现了零排放。
应当说明的是:粉煤灰也可以使用本发明的方法进行铝酸钠的生产,而且在配料中,粉煤灰无需经过破碎磨细处理即可直接应用,使本发明的方法流程更短、效率更高。

Claims (10)

  1. 一种钙铁榴石一步碱热法处理中低品位铝土矿生产铝酸钠的方法,其特征在于:包括下述步骤,
    S1:将中低品位铝土矿破碎磨细成矿粉;
    S2:将矿粉、铁酸钠、活性石灰和循环母液混合制备成原料矿浆;
    S3:将原料矿浆进行碱热溶出反应,反应结束后得到溶出矿浆;
    S4:将溶出矿浆稀释得到稀释液,将稀释液进行液固分离,得到溶出渣和溶出液,其中溶出液为铝酸钠溶液;
    S5:将铝酸钠溶液蒸发后加晶种结晶并固液分离,得到铝酸钠和高分子比铝酸钠溶液;
    S6:将所述高分子比铝酸钠溶液进行调制,制成步骤S2中所用的循环母液。
  2. 根据权利要求1所述的钙铁榴石一步碱热法处理中低品位铝土矿生产铝酸钠的方法,其特征在于:所述中低品位铝土矿的硅铝比为2~6。
  3. 根据权利要求1所述的钙铁榴石一步碱热法处理中低品位铝土矿生产铝酸钠的方法,其特征在于:铝土矿、铁酸钠、活性石灰组成的原料矿浆中,各形态存在的铁、铝、钙、硅总量分别以氧化物计,配料配方如下:
    氧化铁的总量与氧化铝的总量的质量比为0.2~0.6∶1;
    氧化钙的总量与氧化铁的总量的摩尔比为3~6∶1。
  4. 根据权利要求1所述的钙铁榴石一步碱热法处理中低品位铝土矿生产铝酸钠的方法,其特征在于:所述原料矿浆的液固比为2~5∶1。
  5. 根据权利要求1所述的钙铁榴石一步碱热法处理中低品位铝土矿生产铝酸钠的方法,其特征在于:步骤S6中所述高分子比铝酸钠溶液进行苛碱浓度调制后得到循环母液,其中,循环母液中的苛碱浓度为150~250g/L,分子比为5~25。
  6. 根据权利要求1所述的钙铁榴石一步碱热法处理中低品位铝土矿生产铝酸钠的方法,其特征在于:步骤S3中溶出反应的温度为150~250℃, 反应时间为0.5~2h。
  7. 根据权利要求1所述的钙铁榴石一步碱热法处理中低品位铝土矿生产铝酸钠的方法,其特征在于:所述方法还包括:
    步骤S7:将步骤S4中的溶出渣进行洗涤并固液分离,得到钙铁榴石型渣和洗涤液;
    步骤S8:将所述洗涤液用于步骤S4中稀释所述溶出矿浆。
  8. 根据权利要求1所述的钙铁榴石一步碱热法处理中低品位铝土矿生产铝酸钠的方法,其特征在于:步骤S5具体包括下述步骤:
    S51:将晶种加入到蒸发后的铝酸钠溶液进行结晶,得到结晶浆料;
    S52:将结晶浆料进行液固分离,得到高分子比铝酸钠溶液和铝酸钠固体。
  9. 根据权利要求8所述的钙铁榴石一步碱热法处理中低品位铝土矿生产铝酸钠的方法,其特征在于:步骤S51中的结晶温度为85~40℃,结晶时间为10~30h,晶种添加量为10-200g/L。
  10. 根据权利要求1所述的钙铁榴石一步碱热法处理拜耳法赤泥生产铝酸钠的方法,其特征在于:步骤S1中的铁酸钠是含铁原料与工业碳碱烧结而成。
PCT/CN2018/092423 2017-06-23 2018-06-22 钙铁榴石一步碱热法处理中低品位铝土矿生产铝酸钠的方法 WO2018233687A1 (zh)

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