Phosphorus selection process in low-phosphorus and low-iron ore

15311826613

Welcome to consult Xinhai - customized mineral processing plan

Xinhai can provide you with mineral processing tests, mineral processing process and mineral processing equipment selection, mineral processing plant scheme design and construction drawing design; provide mining mineral processing equipment; provide mineral processing plant construction and equipment installation as well as mine management and operation services.

Consultation 153-1182-6613

15311826613

Click to add WeChat

Get product price

WeChat ID has been copied, add friends, and get manufacturer quotations!

In the development and utilization of mineral resources, low-phosphorus and low-iron ore is a relatively special type of ore. For this kind of ore, how to effectively select the phosphorus element in it and improve the comprehensive utilization value of the ore is an important issue facing the field of mineral processing. This article will introduce the ore properties of low-phosphorus and low-iron ore and the phosphorus selection process of low-phosphorus and low-iron ore.

Ore properties of low-phosphorus and low-iron ore

Low-phosphorus and low-iron ore usually refers to an ore type with low phosphorus content and relatively low iron content in iron ore. The main mineral composition of this ore may include iron minerals such as magnetite, hematite, siderite, and a small amount of phosphorus-containing minerals such as apatite.

This type of mineral has a complex composition. In addition to iron minerals and phosphorus-containing minerals, it may also contain other impurity minerals, such as quartz, feldspar, mica, etc. The presence of these minerals will have a certain impact on the phosphorus selection process. In addition, the ore has low phosphorus and iron contents, and the particle size distribution is uneven, with both coarse-grained and fine-grained ores.

Phosphorus selection process of low-phosphorus and low-iron ore

The ore properties of low-phosphorus and low-iron ore are complex and the content is low. It is difficult to select ore. The commonly used method is flotation. According to the different properties of the ore, combined methods are also used for selection, such as magnetic separation-flotation combined method and gravity separation-flotation combined method.

1. Flotation of low-phosphorus and low-iron ore for phosphorus selection

Flotation is a common method for phosphorus selection. Its principle is to use the difference in physical and chemical properties of the mineral surface and add flotation agents to separate phosphorus minerals from other minerals. Generally, the low-phosphorus and low-iron ore is crushed and ground to make the minerals in the ore reach a monomer dissociation state, and then the flotation agent is added, stirred evenly and sent to the flotation machine for flotation. During the flotation process, phosphate minerals are adsorbed by flotation agents, attached to bubbles and float to the surface of the pulp to form a foam product, namely phosphate concentrate; while other minerals remain in the pulp and become tailings.

Flotation is suitable for processing various types of low-phosphorus and low-iron ores, and has relatively low requirements for the particle size and mineral composition of the ore; by selecting appropriate flotation agents and process parameters, phosphate minerals can be effectively separated from other minerals, and the recovery rate of phosphorus can be improved. However, the consumption of flotation agents in this method is large and the cost is high. At the same time, a large amount of water is consumed during the flotation process, and the wastewater generated is difficult to treat.

2. Magnetic separation-flotation combined phosphorus selection

Magnetic separation-flotation combined method is a method for phosphorus selection that combines magnetic separation and flotation. First, the magnetic separation method is used to separate the iron minerals in the low-phosphorus and low-iron ore to obtain iron concentrate and non-magnetic minerals. Then the non-magnetic minerals are ground and floated to select the phosphorus minerals and obtain phosphorus concentrate.

This method can recover iron and phosphorus at the same time, realize the comprehensive utilization of ore, and improve resource utilization. Then, the iron minerals are separated in advance by magnetic separation, which can reduce the processing volume in the subsequent flotation process and reduce the consumption and cost of flotation reagents. However, this method has certain requirements for the mineral composition and particle size distribution of low-phosphorus and low-iron ores, and a reasonable process design is required based on the specific properties of the ore.

3. Gravity-flotation combined phosphorus selection

First, the ore is crushed and ground to make the minerals reach a monomer dissociation state, and then gravity selection is carried out. The density difference of the minerals is used to initially separate a part of the phosphorus-containing minerals and other heavy minerals, and at the same time, some impurity minerals with higher density are removed to improve the selection grade of subsequent flotation operations. After the concentrate obtained by gravity selection is processed, it is combined with the gravity selection tailings to enter the flotation operation. During the flotation process, appropriate flotation agents are added to make the phosphorus-containing minerals hydrophobic, attached to the bubbles and floated to form a foam product, namely, phosphate concentrate, while other minerals remain in the slurry as tailings.

Phosphorus selection of low-phosphorus and low-iron ores is a complex process, and it is necessary to select appropriate phosphorus selection process methods according to the specific properties of the ore. Flotation, magnetic separation-flotation combined method and gravity-flotation combined method each have their own characteristics and scope of application. In practical applications, a variety of process methods can be combined and optimized to improve phosphorus selection effect and resource utilization. At the same time, it is necessary to continuously explore new phosphorus selection technologies and processes to reduce costs, reduce environmental pollution, and realize the efficient and green development and utilization of low-phosphorus and low-iron ores.