What is the metal phase? What is the significance of mineral processing?

The phase analysis is mainly based on the solubility and dissolution rate of various minerals in the ore in various solvents. Different concentrations of various solvents are used to treat the analyzed ore samples under different conditions, so that various minerals in the ore are separated. Thus, it is possible to measure the presence and amount of a certain mineral in a sample.

Spectral analysis and chemical analysis can only find out the types and contents of the elements contained in the ore. It is not possible to indicate the presence of various compounds. Only through phase analysis and rock identification, can we know an element in the ore. What minerals are present.

According to the available data, the following elements can be analyzed for phase:

Copper, lead, zinc, manganese, iron, tungsten, tin, antimony, cobalt, bismuth, nickel, titanium, aluminum, arsenic, mercury, silicon, sulfur, phosphorus, molybdenum, germanium, indium, beryllium, uranium, cadmium and the like.

The various elements need to be analyzed for which phases, and the relevant information can be found, and will not be described here.

Compared with rock and mineral identification, which relies on microscopic analysis as the main method, the phase analysis operation is faster and accurate, but it cannot distinguish all minerals one by one. More importantly, it is impossible to determine the spatial distribution and embedding of these minerals in the ore. The mosaic relationship is therefore only an auxiliary method in the study of ore material composition, and it is impossible to replace the rock mineral identification.

For the mineral processing staff, it is not necessary to master the technology of phase analysis. It is mainly to understand what elements can be analyzed by the phase analysis. Which phases should be analyzed for each element? Minerals exist? What are the options for various minerals? For example, a tungsten ore, spectral analysis only knows the approximate content of tungsten, chemical analysis knows the content of tungsten oxide, but whether the tungsten oxide is scheelite or black tungsten Mine, or both, must be determined through comprehensive analysis such as phase analysis and rock and mineral identification: if it is scheelite, re-election or flotation method can be adopted according to its embedding particle size; Generally, only the re-election method is adopted; if both are available, the heavy-floating joint method can be used. With these basic concepts, we can put forward reasonable requirements for the phase analysis, in order to correctly analyze and apply the phase analysis data drafting plan. If you can't do it now, don't send the phase analysis.

Due to the complex nature of the ore, some elemental phase analysis methods are not mature enough or are still in the process of research and development. Therefore, it is necessary to comprehensively analyze the data obtained by phase analysis, rock ore identification or other analytical methods to obtain correct conclusions.

Silver phase

Silver chloride, silver manganese oxide adsorption silver, natural silver silver, silver sulfide silver, galena silver, sphalerite coated silver, pyrite and arsate silver, quartz , silicate wrapped silver

Aluminum phase

Gibbsite phase, chlorite, hydromica phase, kaolinite, sericite phase, gibbsite phase

Gold phase

Bare and semi-naked natural gold, carbonated gold, sulphide-coated gold, limonite wrapped gold, quartz and silicate-coated gold

Carbon phase

Carbon, organic carbon, graphitic carbon in carbonate

Calcium phase

Calcium carbonate, fluorite , calcium oxide in silicate minerals

Cobalt phase

Cobalt in oxide, cobalt in sulfide, cobalt in gangue

Copper phase

Oxide copper, copper sulfide, combined phase copper

Iron phase

Magnetic iron, iron carbonate, erythro iron, pyrite, iron silicate

Manganese phase

Manganese carbonate, manganese in pyrolusite, manganese in manganese-bearing hematite, manganese in silicate

Molybdenum phase

Oxide phase molybdenum, iron combined phase molybdenum, sulfide phase molybdenum

Phosphorus phase

Phase apatite phosphorus, iron oxides of phosphorus, phosphorus phase monazite, xenotime phase P

Lead phase

Oxide phase lead, sulfide phase lead, combined lead

Sulfur phase

Natural sulfur , sulfur in sulfate, sulfur in sulfide

Sputum

Yanhua and Fangyu Mine, sulphide, samarium and strontium ore

Titanium phase

Rutile, titanium in ilmenite, titanium in vermiculite and silicate, titanium in titanium magnetite

Tungsten phase

Determination of Tungsten, determination of scheelite, determination of wolframite

Zinc phase

Oxide phase zinc, sulfide phase zinc, and iron combined phase zinc

Nickel phase

Nickel sulfate, nickel sulfide, nickel silicate

Chromium phase

Chromium in magnetite, chromium in silicate, chromium in chrome spinel  

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