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Gold Science and Technology ›› 2019, Vol. 27 ›› Issue (6): 941-949.doi: 10.11872/j.issn.1005-2518.2019.06.941

• Mining Technology and Mine Management • Previous Articles     Next Articles

Study on the Process Mineralogy of Refractory Gold Concentrate in Zhenyuan, Yunnan Province

Qihao GUI1,2(),Shixing WANG1,2,Libo ZHANG1,2(),Jinqing ZHENG3   

  1. 1. Faculty of Metallurgical and Energy Engineering,Kunming University of Science and Technology,Kunming 650093,Yunnan,China
    2. Key Laboratory of Unconventional Metallurgical Ministry of Education,Kunming 650093,Yunnan,China
    3. Yunnan Jinshan Mining Co. ,Ltd. ,Kunming 654100,Yunnan,China
  • Received:2018-12-12 Revised:2019-03-01 Online:2019-12-31 Published:2019-12-24
  • Contact: Libo ZHANG E-mail:G624739569@163.com;zhanglibopaper@126.com

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Abstract:

Zhenyuan gold deposit belongs to fine disseminated gold deposits located in Ailao Mountain.This type of gold ore is often associated with sulfide and carbon,which could diminish the gold cyanidation leaching efficiency and reduce the gold recovery efficiency in the next step.In order to guarantee the recovery rate of gold,the process mineralogy has to be proceeded to ensure the gold wasn’t been wasted due to the improper process.X-ray diffraction,X-ray fluorescence,Energy Dispersive X-Ray Spectroscopy,particle size test and mineral liberation analysis have been used to determine the chemical composition,mineral composition,particle size and the characteristic of Zhenyuan refractory gold ore obtained from Zhenyuan gold deposit.The X-ray diffraction,X-ray fluorescence,Energy Dispersive X-Ray Spectroscopy and mineral liberation analysis(MLA) shows that the main phase of the concentrate is sulfide(32.37% of pyrite,0.58% of stibnite and 0.46% of arsenopyrite),carbonate,silicate and the chemical component of concentrate is mainly iron(10.86%),sulfur(12.48%),silicon(18.56%).Meanwhile 0.87% of arsenic and 5.55% of carbon(3.18% organic carbon and 2.37% inorganic carbon) have been found from the sample,which is harmful to cyanidation process. The particle size,encapsulation and exposure of pyrite,stibnite and arsenopyrite were analyzed with particle size test and MLA test. The particle size of sulfide is mainly between 10~75 μm,about 90%.A large number of sulfide is fully encapsulated(83.6%),only few of them are totally covered with gangue(0.9%).Gold diagnostic leaching and MLA test were carried out to determine the occurrence state of gold.Sodium cyanide,acetonitrile,nitric acid and fire-assaying method has been used to determine the gold chemical content in native gold,sulfide,carbon and silicate.The gold diagnostic leaching result shows that 96.16% of gold is covered with sulfide and few is in the form of native gold or covered with silicate and carbonate.No gold is wrapped in carbon.MLA test could automatically diagnose different phase of gold ore based on electron software,energy spectrum and MLA software.It also could built standard data base of sample ore and calculate the process mineralogy data automatically.From the MLA test,the electron microscopy (SEM) images of sulfide and native gold has been collected and analyzed,which shows the similar result with gold diagnostic test that most of the gold is wrapped in sulfide. According to the mineralogy process which have proceeded,this gold concentrate is a carbon-baring sulfide gold ore.Since most of the gold is fully covered with sulfide,the sulfide removing process is becoming necessary.It is recommended that oxidation or grinding process should be proceeded before gold leaching process.

Key words: gold concentration, mineralogy, phase analysis, occurrence state, embedding relation, diagnostic leaching

CLC Number: 

  • TD953

Table 1

Element composition of gold concentration(%)"

成分w(B)成分w(B)
O32.51有机碳3.18
Si18.56无机碳2.37
S12.48Pb0.03
Fe10.86As0.87
Al7.58Au*23.7
Zn0.09其他17.43

Table 2

Mineral composition and content of gold concentrate"

矿物质量分数/%矿物质量分数/%
黄铁矿32.37石英18.92
辉锑矿0.58绢云母9.33
毒砂0.46钾长石5.37
闪锌矿0.14黝帘石6.73
方铅矿0.04透闪石2.62
黄铜矿0.04斜长石1.79
黝铜矿<0.01绿泥石1.15
自然金、碲金银矿<0.01黑云母0.45
重晶石0.05金云母0.52
金红石0.09黏土矿物0.16
白云石13.13磷灰石0.22
方解石1.10锆石0.01
菱铁矿1.20其他矿物0.35
有机碳3.18--

Table 3

Particle size, encapsulation and exposure of sufide in gold concentration"

表面暴露情况占比/%连生情况占比/%不同粒度硫化物占比/%
与碳酸盐与硅酸盐与其他矿物<10 μm10~20 μm20~38 μm38~75 μm75~150 μm150~200 μm
合计1002.713.40.32.121.534.536.64.90.4
完全裸露83.6---0.518.830.829.73.40.4
部分裸露15.52.512.70.31.12.43.66.91.5-
完全包裹0.90.20.700.50.30.1---

Fig.1

SEM images of pyrite"

Fig.2

Characteristic images of stibnite particle(patterns of MLA)"

Fig.3

SEM images of pyrite"

Fig.4

Oxidation at the edge of the stibnite(“+” location)"

Fig.5

Characteristic images of arsenopyrite particle(patterns of MLA)"

Fig.6

SEM images of pyrite"

Fig.7

Result of sp-tip gravity beneficiation"

Table 4

Characteristic of independent gold mineral in gold cencentration"

序号矿物成分及含量/%粒度/μm解离—连生情况
AuAgTeFe
1自然金99.550.4532.8×29.0解离单体
2自然金100.0040.5×30.0解离单体
3自然金100.0021.5×16.3解离单体
4自然金99.120.8831.6×29.0解离单体
5自然金99.360.6446.5×35.3解离单体
6自然金100.002.2黄铁矿包裹
7自然金100.004.0黄铁矿颗粒边缘
8碲金银矿36.3721.2540.461.9416.0解离单体

Fig.8

SEM images of gold"

Fig.9

Energy spectrum of petzite"

Table 5

Leaching result of gold in concentrate"

金的赋存形式质量分数/(×10-6)占比/%
合计24.74100.00
裸露金0.281.13
碳酸盐及氧化物包裹金0.160.65
硫化物包裹金23.7996.16
硅酸盐及其他包裹金0.512.06
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