冶炼

For KISC, the technology shall firstly use high-phosphorus ironstone efficiently which can not completed by the current picking technology or blast furnace process, to greatly reduce ironstone cost that occupies the most proportion of iron and steel production cost, easy cost pressure caused by international and domestic shortage of production materials, induce transportation risk, to assuringly supply KISC with a great deal of cheap raw materials and create great economic profit; Secondly it shall promote KISC to update its products, especially high-added-value products of lowest phosphorus and lowest sulfur, to enhance its ability to adapt market and gain profit; Thirdly it shall improve technical and economic indexes of blast furnace and converter, and be helpful for efficient blast smelting and less-slag melting of converter process; Furthermore the technology shall greatly promote the stable operation of melting process and the control of the production of high-temperature and high-quality casting blank, to realize efficient continuous casting and continuous casting and rolling to improve KISCs production intensification; Finally the technology shall distribute melting functions and optimize production processes, to improve the auto-control of melting and continuous casting, to realize the integrated management of technology, equipment, production organization and management, logistic management, and production running of smelting, continuous casting and rolling.

对昆钢而言，该技术的应用，首先可以经济有效地实现现有采选技术及高炉冶炼所不能完成的高磷铁矿石的利用，大幅度降低在钢铁生产中占绝大比例的原料成本，缓解国际国内生产原料紧张而造成的成本压力，为昆钢创造巨大的经济效益；其次可以促进昆钢产品的升级换代特别是高附加值超低磷、超低硫钢种的开发，增强昆钢的市场适应能力和效益创造能力；再次可促进高炉及转炉技术经济指标的改善，降低生产成本，且利于转炉生产实现高效吹炼和少渣冶炼；此外，该工艺能显著提高冶炼环节的平稳顺行及高温、高质量铸坯生产的可控程度，可实现高效连铸和连铸连轧生产，提高昆钢生产的集约化程度；最后，该工艺能实现冶炼功能的分工和生产流程的优化，可提高昆钢炼钢与连铸生产的计算机自动控制程度，有效促进炼钢—连铸—轧钢的工艺、设备、生产组织和管理、物流管理、生产操作等环节的一体化管理的实现。

According to current smelting process and production data,the method for predicting end-point phosphorus content of BOF was investigated.

根据现场的冶炼工艺和生产数据，研究了转炉冶炼终点磷的预报方法；采用机理模型和偏最小二乘模型分析了终点磷的影响因素；建立了基于偏最小二乘回归的转炉终点磷的预报模型。

The preventive measures for the harmful defects of alkali metals are as follows: 1, reducing the alkali metals content in the raw materials; 2, increasing the MgO content of the sinter , decreasing the basicity of slag , decreasing the Si content of the pig iron, increasing relative slag volume; 3 , introducing prereduced ore pellets or partly reducted sinter; 4increasing the ability of coke resisting alkali metals; 5, using refractories that have the ability of resisting corrasion of alkali metals; 6 , cleaning the blast furnace periodically. The above recommendations are necessary for decreasing the circulation and accumulation of alkali metals effectively in blast furnace, reducing the harmful influence of alkali metals on blast furnace, increasing the smelting intensity, decreasing the coke rate, improving the gas permeability.

基于碱金属对高炉冶炼的上述危害，本文结合湘钢高炉的实际生产情况，通过理论分析、计算以及其他钢厂防治碱害的经验，提出防治高炉碱害的措施：1、减少入炉原、燃料的碱金属含量；2、提高烧结矿中的MgO含量、降低炉渣碱度、降低生铁含硅量、适当增加渣量；3、采用预还原的金属化球团或部分还原的烧结矿；4、提高焦炭的抗碱能力；5采用抗碱侵蚀的耐火材料；6、周期性性洗炉，以有效地减少碱金属在高炉内的循环富集，降低碱金属对高炉的危害，提高高炉的冶炼强度，降低焦比，改善高炉透气性。

In addition, the company formed an excellent team of technical services for domestic enterprises to design and construction of a number of Units ferrosilicon smelting furnace and smelting technology provides businesses with advice and guidance, in the industry enjoyed a high reputation.

另外，公司组建了一支非常优秀的技术服务队伍，为国内企业设计并修建了数台硅铁冶炼炉，并为企业提供冶炼技术咨询和指导，在业内享有很高的声誉。

Some measures have been taken to maintain the furnace condition such as optimizing smelting operation,intensifying slag splashing and improving the method of fettling.

转炉炉壁厚达到300mm左右时进入炉役后期，通过优化冶炼操作、强化溅渣护炉、补炉方法维护炉况，实现冶炼品种钢的目的，取得了明显效果。

Ta,Mo,W,Ti,Nb,the refractory impurity elements,in RE metals are dissolved thoroughly with the addition of fluoric acid,and then determined by ICP-MS.

在稀土金属的冶炼过程中，常用到一些由难熔金属制成的冶炼容器，这样极易引入相应的难熔金属杂质，如Ta、Mo、W、Ti、Nb等。

The common methods of reclaiming indium from the byproducts of lead metallurgy and zinc hydrometallurgy are enumerated, and analyzed every method's virtue and shortcoming.

主要列举了从铅冶炼和锌湿法冶炼过程的副产品中回收铟的常用方法，并分析了各种方法的优缺点。

Through characteristic analysis on the vanadic titanomagnetite smelted in BF,it is realized that the injection of pulverized coal is advantageous to smelting vanadic titanomagnetite in blast furnace under the condition of complete combustion.

通过分析钒钛磁铁矿高炉冶炼的特殊性，认为在保证煤粉燃烧率的前提下，喷煤更有利于钒钛磁铁矿高炉冶炼，其煤比可以赶上普通矿高炉冶炼的领先水

Recent progress and achievements of tungsten metallurgy in China including the exploitation of process technique in treating various resource, molybdenum separation technology from tungsten, production of high pure APT from low grade material and tungstenic scrape, process equipment and automatization degree in tungsten metallurgical plant, application of membrane technology in non pollution tungsten metallurgical process, and ultrafine powder of tungsten etc.

综述了近年来我国钨冶炼在开发处理多种资源的工艺技术、钨钼分离技术、从低品位钨矿物原料和含钨废料中生产高纯APT、钨冶炼技术装备和自动化水平、膜分离技术在开发无污染钨冶炼工艺的应用、超细钨粉等方面的最新进展和成果。

This changes the costs and profit of the common oreand vanadic and titanic ore. The rate of the common ore and vanadic and titanic orechanges with the profit's change.

因此，找到普通矿冶炼和钒钛矿冶炼二者最佳的比例值，根据生产成本及市场价格的变化，及时调整普通矿冶炼和钒钛矿冶炼的比例，以获取最佳的经济效益是非常有意义的工作。

hydrometallurgy：湿法冶炼

湿法冶炼(hydrometallurgy ) 指利用溶剂,借助于氧化、还原、中和、水解、 络合等化学作用,对原料中金属进行提取和分 离,得到金属或其化合物的过程. 火法冶炼(pyrometallurgy ) 指利用高温(超过金属熔点温度)从矿物中提取 金属或其他化合物的方法;

METE：有色金属(冶炼部分)

,"钢铁研究学报","IRON",4 | ,"有色金属(冶炼部分)","METE",5 | ,"轻金属","QJSS",6

nonferrous metallurgy：非铁金属冶炼术

nonferrous metal 有色金属 | nonferrous metallurgy 非铁金属冶炼术 | nonflatness 不平面度

puddling process：搅拌炉熟铁冶炼法

puddling basin 搅炼炉膛 | puddling process 搅拌炉熟铁冶炼法 | Puddling process 普德林炼熟铁法

smelt：冶炼

锻造(Smithing):这种方式是使用你从矿脉挖到的矿石,经冶炼(smelt)之后成为金属块,然后使用(use)金属块在铁砧(anvil)上,同时需要有铁槌(hammer)在玩家的物品栏里.

smelter：冶炼者;熔炉

smeller 地质学家;含硫气井 | smelter 冶炼者;熔炉 | smeltery 冶炼厂

Vance：冶炼金属

483.vanca金属 | 484.vance冶炼金属 | 651.vancey冶炼金属的

Uncommon metal foundries：稀有稀土金属冶炼业

463,,,,\\"3339\\",\\"Other noble metal foundries\\",\\"其他贵金属冶炼... | 464,,,\\"334\\",,\\"Uncommon metal foundries\\",\\"稀有稀土金属冶炼业\\" | 465,,,,\\"3341\\",\\&quot

Noble metal foundries：贵金属冶炼业

459,,,,\\"3329\\",\\"Other light non-ferrous metal foundries\\",\\"其他轻有色金属冶炼业\\" | 460,,,\\"333\\",,\\"Noble metal foundries\\",\\"贵金属冶炼业\\" | 461,,,,\\"3331\\&amp

Refineries Capacity Utilization：冶炼利用率

Secondary Refined Production二次冶炼生产量 | Refineries Capacity Utilization(%)冶炼利用率 | Secondary Refined as % in Total Refined Prod.二次冶炼占总量的比率