As the core equipment in the field of mineral processing, the ore dressing ball mill occupies an important position in the global mine development with its unique crushing principle and process adaptability. This article will conduct a systematic analysis from three dimensions: ore applicability, technical advantages and typical application scenarios.

1. Adaptable ore type characteristics

The ball mill is suitable for processing ores with a hardness between 5-12 and medium-fine particle size, which can be divided into four categories:

‌Metallic ore‌: including iron ore (magnetite/hematite), copper ore (chalcopyrite/bornite), gold ore (gold-containing quartz veins), etc. For example, an iron ore dressing plant uses a Φ3.6×6m wet ball mill to process ore containing 45% iron. After two stages of grinding, the concentrate grade reaches 67%.

‌Non-metallic ore‌: In the processing of materials such as quartz, feldspar, and fluorite, the dry ball mill can grind the raw materials to 80-400 mesh, which meets the fineness requirements of the glass and ceramic industries. A quartz sand project adopts a graded lining design, and the processing capacity of a single device reaches 25t/h.

‌Rare metal ores‌: For low-grade ore bodies such as spodumene and tungsten ore, selective dissociation is achieved by adding steel ball media. A tungsten mine in Jiangxi uses an overflow ball mill, and the matching spiral classifier increases the grinding efficiency by 18%.

‌Complex symbiotic ores‌: For polymetallic ores such as lead-zinc ore, copper-molybdenum ore, etc., a stage grinding-stage separation process is adopted. A polymetallic mine in Yunnan achieves effective separation of sulfide and gangue by adjusting the mill speed (critical speed 75%-88%).

2. Typical industrial application scenarios

‌Metal ore beneficiation process‌: In the iron ore flotation process, the ball mill is used as a second-stage grinding equipment to grind 3-5mm coarse concentrate to -200 mesh, accounting for 85%, and cooperates with a magnetic separator to obtain high-grade concentrate. A super-large iron ore uses a semi-autogenous grinding + ball mill unit, reducing energy consumption by 22%.

‌Purification of non-metallic minerals‌: Kaolin processing uses an intermittent ball mill, and by controlling the grinding time (4-8h) and the medium ratio (Φ30-60mm ceramic balls), a fine product with a whiteness of >92% is obtained.

‌Rare metal extraction‌: In the processing of lithium mica ore, the vibrating ball mill achieves layered structure dissociation through high-frequency impact, and the grinding power consumption is reduced by 30% compared with traditional equipment, and the lithium recovery rate is increased to 78%.

‌Complex ore processing‌: For copper oxide ore with high mud content, a grid-type ball mill and a hydrocyclone closed-circuit system are used to solve the slurry viscosity problem by adjusting the width of the discharge seam (8-15mm).

3. New trends in technological development

With the advancement of intelligent mine construction, new ball mills are developing towards high efficiency and energy saving: using magnetic liners (life extended by 3 times), variable frequency drive systems (energy saving 15%-25%), and online particle size monitoring and other technologies. After a gold concentrator introduced the Internet of Things control system, the unit cost of the grinding section dropped by 0.8 yuan/ton.

The technical advantages of the ore dressing ball mill lie in its wide material adaptability, precise particle size control capability and mature process supporting system. In the future, with the integration and application of new materials and intelligent control technology, this type of equipment will play a more critical role in the development of complex mineral resources. When selecting a model, enterprises should focus on the hardness of the ore, the embedding characteristics and the target particle size, and select the optimal configuration solution based on the production capacity requirements.