莫桑比克中北部滨海锆钛砂矿成矿地质特征

莫桑比克东濒印度洋,沿海岸线赋存丰富的具有世界级规模的滨海砂矿资源,具有较好的勘探和开发投资前景。通过野外地质调查和室内综合研究,对莫桑比克中北部滨海砂矿的成矿地质背景、矿体特征、矿石特征及矿床成因进行总结。本区滨海锆钛砂矿赋存于第四系粉细砂层中,地貌上多为起伏砂地和平坦砂地,矿体沿海岸线呈条带状分布,延展连续性较好,形态较规则。沿倾向矿石品位较连续,矿体厚度总体上变化不大,各重矿物在矿体中的含量变化呈正相关关系。重矿物以钛铁矿为主,其次为锆英石、金红石、独居石,多以单矿物颗粒的状态散布在矿石中,粒度主要为0.096～0.15 mm,属易分选型矿石。矿床类型属滨海相机械沉积型矿床,其形成受成矿物质来源、气候和水动力、海岸地貌、构造运动与海岸变迁等多种因素影响,主要经历三个阶段,即重矿物原生赋存阶段、运移阶段和富集成矿阶段。本工作揭示了滨海砂矿形成规律,为莫桑比克中北部滨海砂矿矿床勘探和开发提供了参考。     

西北某钒钛磁铁矿矿石的工艺矿物学研究

西北某矿石属低硫含磷的酸性低品位原生钒钛磁铁矿矿石,通过镜下鉴定、X射线衍射分析和扫描电镜分析等多种手段对原矿的化学成分、矿物组成及含量、矿物的产出形式、矿石的结构构造、主要目的矿物的嵌布粒度等进行了详细的工艺矿物学研究,查明矿石的工艺学特性.研究结果表明,该矿石具浸染状构造和交代构造,其中铁矿物主要是钛磁铁矿和赤铁矿,钛矿物包括钛铁矿、金红石和榍石等.钛磁铁矿和钛铁矿均属不均匀细粒—微细粒嵌布特征,在-400目占95%左右的磨矿细度条件下,通过选矿可获得铁精矿和钛精矿两种产品.     

海南岛海砂资源的分类特征及成矿特点分析

海南岛海砂资源丰富,质量较好,储量位居全国前列,其中钛铁矿、锆英石和独居石是海南岛的优势滨海砂矿资源。根据其用途主要分为3类: 锆钛砂矿、石英砂矿和建筑用砂矿。通过资料收集和整理,分别研究了海南岛不同类型海砂资源的分布范围、勘查程度、资源储量、形成环境和资源潜力等。研究结果表明: 锆钛砂矿开发程度最高,主要分布于琼东沿海及水下阶地一带的全新统,规模较大,品位较高,开发条件较好; 琼西则以建筑用砂矿和石英砂矿为主,海砂质量好,杂质含量较低; 位于浅海区的潮流沙脊和河口三角洲,工作程度不高,但其海砂分布广、厚度大、砂质好,是今后海砂勘查的重点区域,具有良好的资源开发前景。总结海南岛海砂资源的主要成矿特点为: ①分布广泛,规模巨大,开发条件好; ②主要产于全新世地层; ③沉积厚度较大,纵向连续性好; ④海砂质量较好,并富含重矿物。     

沉积型钛铁矿品位计算方法

沉积型钛铁矿品位计算中时常出现简化计算公式,忽视钛铁矿中TiO2实际含量和钛物相分布中钛铁矿占比等因素,导致钛铁矿品位计算数据偏差,影响钛铁矿储量计算和项目经济测算。为了减少钛铁矿品位计算的错误,本文以莫桑比克和马拉维钛铁矿项目勘查资料数据为基础,论述钛铁矿物中TiO2实测含量及钛物相分析中钛铁矿占比的意义,正确运用钛铁矿品位计算公式,使沉积型钛铁矿品位计算更接近实际,为提升钛铁矿砂矿资源储量和项目经济性测算的准确性提供重要支撑。     

沉积型钛铁矿品位计算方法

沉积型钛铁矿品位计算中时常出现简化计算公式,忽视钛铁矿中TiO2实际含量和钛物相分布中钛铁矿占比等因素,导致钛铁矿品位计算数据偏差,影响钛铁矿储量计算和项目经济测算。为了减少钛铁矿品位计算的错误,本文以莫桑比克和马拉维钛铁矿项目勘查资料数据为基础,论述钛铁矿物中TiO2实测含量及钛物相分析中钛铁矿占比的意义,正确运用钛铁矿品位计算公式,使沉积型钛铁矿品位计算更接近实际,为提升钛铁矿砂矿资源储量和项目经济性测算的准确性提供重要支撑。     

山东沂水县常庄钛铁矿地质特征及成因探讨

沂水县常庄钛铁矿床产于中细粒含钛磁铁矿辉石角闪石岩中,该岩体既是成矿母岩又是赋矿围岩。矿体长1 800 m,平均宽75 m,控制斜深344 m,平均品位TiO28.85%,品位变化系数为104%,TFe＋TiO2平均品位28.24%,品位变化系数为102%。属品位变化较不均匀的矿体。该矿床具有矿体规模大,形态简单,易于开采之特点。通过对矿床地质特征的研究,认为该矿床属基性岩浆分异型钛铁矿床,其成矿时代为古元古代。     

南海及邻域砂矿资源分布特征及成矿模式

南海及邻域具有多样的地形地貌和丰富的物源,为海洋固体矿产资源的形成和分布提供了物质来源和堆积环境。为系统查明南海及邻域砂矿资源分布情况,本文通过对南海及邻域2606个站位表层沉积物样品进行粒度测试、碎屑矿物鉴定,以及重矿物的品位计算,分析了南海及邻域有用矿物砂矿资源以及建筑用砂资源分布特征并预测了远景区,总结了砂矿成矿模式。结果表明,南海及邻域具有远景的矿种主要有锆石、钛铁矿、金红石、锐钛矿、独居石和石榴子石等;重矿物高品位矿点主要集中在南海东北陆架、菲律宾海盆、南部陆架,重矿物异常区主要位于周缘陆架浅水区以及越东外陆架浅水海域、菲律宾海盆。锆石品位异常区的范围最大,达到工业品位的面积也最大;其次是磁铁矿、钛铁矿、独居石的异常区;锐钛矿、金红石异常区的面积相当;石榴子石品位异常范围最小。根据砂矿的分布规律、大地构造背景、成矿条件以及成矿元素特征,圈定了24个有用重矿物砂矿成矿远景区和6个成矿带。沉积物中砂（0. 063~2 mm）含量大于50%的建筑用砂的远景区9个,主要分布于海南岛西南面到台湾海峡南部一线以北海域,其次为南海南部礼乐滩、万安滩、曾母暗沙附近海域,其余海域极为罕见。基于南海砂矿资源分布特征,初步建立了近岸型、潮流砂脊型、古河道埋藏型、峡口型、陆架坡折带型等五种砂矿成矿模式,为海砂资源进一步勘查提供方向和建议。     

我国滨海砂矿及工作刍见

我国的海岸线长,有着利于滨海砂矿的成矿条件.滨海砂矿的研究始于五十年代,近年来,对滨海砂矿的分布特征、成矿带、成矿远景的研究,取得了新的进展.一、我国滨海砂矿的分布1.黄海、渤海滨海砂矿成矿区(1)辽东半岛东海岸金、钛铁矿、锆石成矿带:该区出露岩石主要为前寒武系片麻岩和花岗岩,有较多石英脉、含金破碎带,是本区滨海砂矿物质来源.砂金矿在旅顺等处,锆英石分布在庄河至金县沿海一     

非洲锆矿资源地质特征及勘查开发

非洲的锆资源丰富,沿海岸带成群连片分布。通过对非洲51个锆矿床（点）的地质特征、时空分布及勘查开发历史和现状等进行分析研究,查明非洲的锆资源具有分布集中、规模大、易采易选,伴生矿物种类多,综合利用价值高等特点。非洲已查明锆储量占全球52%,其中莫桑比克、南非、马达加斯加、塞内加尔和肯尼亚集中了非洲99%的锆矿资源。矿床类型以滨海锆砂矿为主,矿体多为平行海岸线的沙丘群,通常为上新世-全新世未固结的薄而平坦的砂层,走向延伸10~100km,重矿物以锆石、金红石和钛铁矿为主,含量2%~12%。非洲锆矿的勘查始于20世纪20年代的尼罗河三角洲,开发始于20世纪50年代的南非,特诺、力拓等大型矿业公司是非洲锆矿开发的主力,济南域潇集团等中资企业近年来积极参与。非洲的锆矿开发主要集中在南非和莫桑比克,近10年来的产量约占全球锆产量的40%,成为全球主要锆资源供应地。马达加斯加和肯尼亚的锆矿资源丰富,是与中国签署共建“一带一路”谅解备忘录的国家,与中国在锆矿资源领域的合作潜力巨大。     

辽东半島沿海一带锆、钛砂矿床的初步認識及工作方法

目前稀有元素对发展我国尖端工业起着重要作用。其中的钛主要用于冶金工业,而锆英石、独居石的用途更为广泛,可用于制造各种高溫合金、特殊光学仪器、耐高溫和高压的絕緣材料以及防止原子射綫等。在锆砂矿中除锆外,还可能富集钛铁矿、钶铁矿、独居石、磷钇矿、金紅石等稀有元素。因此应該     

云南大理洱源腊坪岩浆岩风化壳型钛铁砂矿

腊坪地区TiO2区域高值,有利于钛铁矿形成富集。对三类主要岩浆岩中TiO2含量与重砂淘洗砂矿样含矿率比照,认为辉长岩是钛铁砂矿含矿母岩,且与地形地貌及风化次生堆积条件有关。     

Heavy Mineral Placer Sand Deposits of Kontiagarh Area,Ganjam District,Orissa, India

The Kontiagarh placer deposit in the Ganjam district, Orissa, India extends in northeast direction having a width of 700–1000 m. A total of 187 samples were collected meterwise from 55 bore holes in a grid pattern from beach, frontal, intermediate and back dunes covering an area of approximately 1 km². Light minerals decrease in size from the beach to the back dunes, whereas the size distribution of heavy minerals in the beach and dunes is more or less uniform. The average heavy mineral content in the beach and dunes vary from 9.38% to 24.20%. The heavy minerals are ilmenite, garnet, sillimanite, rutile, monazite, and zircon with trace amounts of magnetite, hornblende, diopside, sphene, tourmaline, and epidote. Heavy minerals are mostly less than 350 µm in size, with a peak distribution in the range between 180 and 125 µm. Ilmenite shows exsolution intergrowth with hematite. Mineral chemistry of ilmenite, hematite, leucoxene, magnetite, monazite and sillimanite are examined by EPMA. Leucoxene is lower in Fe and higher in Ti, Al, Cr and V than ilmenite. The litho‐units of the Precambrian Eastern Ghats Mobile Belt, comprising primarily khondalite, charnockite, calc‐silicate granulite and gneiss, are the source of heavy minerals for this deposit. The bulk sample has 7.30% ilmenite, 5.24% sillimanite, 9.16% garnet, 0.18% rutile, 0.14% monazite, 0.06% zircon and 0.52% other heavy minerals. The deposit has good potential for economic exploitation of ilmenite, rutile, sillimanite, monazite, zircon and garnet.     

Typomorphism and bedrock sources of placer-forming minerals of the Umyt’ya rare metal–titanium placer (Khanty-Mansi Autonomous District)

The paper reports the results of study of the main placer-forming minerals (ilmenite and zircon) from the Umyt’ya coastal–marine placer in the western part of the Khanty-Mansi Autonomous District, Yugra. Microprobe study of 1450 zircon grains taken from the upper and lower ore bodies of the Umyt’ya placer (29 samples) and their comparison with zircon in magmatic rocks from the adjacent folded framing of the North and Nether-Polar Urals (40 analyses) allowed us to recognize five geochemical types of the mineral: Aurbakh (prevailing in the Umyt’ya placer), Severorudnichnyi, Tagil-Kytlym, Shemur, and unknown source. Crystallomorphological characteristics of the identified geochemical types of zircon are given. According to the microprobe data (300 analyses), ilmenite is subdivided into six groups. Comparison of these groups with the composition of ilmenite from magmatic complexes of the North and Nether-Polar Urals showed that they correspond to the same complexes as zircon. Based on peculiarities of the geological structure of the eastern slope of the North and Nether-Polar Urals, four separate areas were identified, each comprising spatially close magmatic complexes regarded as possible sources for ore minerals of the placers: Shchekur’ya–Khorasyur, Yalpigner–Chistop, Vizhai–Ivdel, and Denezhkin Kamen. Based on additional criteria, the Yalpigner–Chistop area was the main source for the Umyt’ya placer.     

金刚石选矿方法与评价

金刚石原生矿和砂矿的选矿方法各有异同,但总体来说可分为粗选和精选两个阶段.粗选主要是利用重选跳汰法来进行,精选采用多种方法联合进行.而质量则是整个选矿过程的关键,质量检查应采取多种方法进行,每个工序和各个级别有不同的质量要求.金刚石总的回收率应不低于95%.     

Applied Mineralogical Studies on Iranian Titanium Deposits

Qara-aghaj and Skandian as hard rock titanium deposit and Kahnooj one as a placer deposit were investigated from applied mineralogical point of view. The mineralogical studies were carried out using XRD, XRF, optical microscopy, scanning electron microscopy and microprobe analysis. These studies indicated that ilmenite and magnetite are main valuable minerals in the studied ores. Pyroxene, olivine and plagioclase are the main gangue minerals in Qara-aghaj ore while chlorite and plagioclase are the major gangue minerals in Skandian ore. Plagioclase, clinopyroxene, amphibole, feldspate and some quartz are the important gangue minerals in kahnooj deposit. In all three ores ilmenite is mainly in the form of ilmenite grains but some lamellae of ilmenite with thickness between 0.1 to 20 μm have been occurred as exsolution textures inside magnetite grains, where the magnetite here can be referred to as ilmenomagnetite. In the hard rock ores some fine ilmenites have been disseminated in silicate minerals. The liberation degree of granular ilmenite was determined 150, 140 and 200 μm for Qara-aghaj, Skandian and Kahnooj, respectively. So, only the granular form of ilmenite is recoverable by physical methods. Some sphene and rutile as titanium containing minerals were observed mainly inside ilmenite phase in kahnooj ore. Some fine rutile was also found inside Skandian ilmenite while there were not any other titanium minerals inside Qara-aghaj ilmenite. Apatite is another valuable mineral which was found only in Qara-aghaj ore. Using SEM and microprobe analysis it was found that there are different amounts of exsolved fine lamellae of hematite inside ilmenite in Qara-aghaj and Kahnooj ores while it was not observed in Sckandian one. The average contents of TiO2 in the lattice of Qara-aghaj, Skandian and Kahnooj ilmenite were determined 51.13, 50.9% and 52.02%, respectively. FeO content of ilmenite lattice for all three samples is clearly lower than the theoretical content. This is due to the substitution of Mg and Mn for some Fe2+ ions in the ilmenite lattice. V2O3 content of magnetite lattice is up to 1%. So, magnetite can be a suitable source for production of vanadium as a by-product in all three deposits.     

青海祁漫塔格矿集区矿产资源可利用性等级评价探索

青海祁漫塔格矿集区成矿条件优越,矿产资源丰富,为了给矿集区矿产资源的开发布局优化提供支撑,通过可利用性等级划分的方法,对该矿集区的部分矿产资源进行了可利用性评价的探索研究。以选矿回收率为依据,分区域、分矿种制定可利用性评价等级表,再根据矿山现场选矿回收率进行“选矿回收率修正值”的计算,对比相应的可利用性评价等级表确定该矿山有用矿物的可利用性等级,最后根据有用矿物的可利用性等级确定该矿山的可利用性等级。结果表明: 祁漫塔格矿集区的15座矿山(矿床)中易利用的占40.00%,中等可利用的占26.67%,难利用的占33.33%。研究结果可为政府矿业部门的管理及开发布局优化提供一定的参考。