7 Faktor yang Mempengaruhi Flotasi Buih

Froth flotation is a crucial mineral processing technique that separates materials based on differences in their surface properties. This process uses air bubbles to selectively recover valuable minerals from slurry, with flotation machines playing a vital role in the operation.

The specific flotation process is as follows: various flotation reagents are added to a slurry of a certain concentration, and through agitation and aeration within the sel flotasi, a large number of dispersed bubbles are generated. At this point, the mineral particles suspended in the slurry collide with the bubbles; some of the floatable mineral particles attach to the bubbles and rise to the surface of the slurry, forming a foam layer, which constitutes the concentrate; meanwhile, the non-floatable minerals remain in the slurry and become tailings. Through this process, the objective of mineral separation is achieved.

7 Critical Factors Impacting Flotation Performance

The froth flotation machine plays an indispensable role in the mineral beneficiation process. Flotation is susceptible to several factors during the process, including grinding fineness, slurry concentration, pulp pH, pharmaceutical system, aeration and agitation, flotation time, water quality, and other process factors. The factors that affect the flotation process are detailed below.

1. Grinding Particle Size

Both coarse-sized minerals (greater than 0.1 mm) and fine-sized minerals (less than 0.006 mm) can affect flotation efficiency and mineral recovery rates.

During coarse-grain flotation, the high specific gravity of the mineral particles makes it difficult for them to remain suspended in the flotation cell, thereby reducing the probability of collision with bubbles. Furthermore, once coarse particles attach to a bubble, they are highly susceptible to detachment due to the significant detachment forces acting upon them. Consequently, under conventional process conditions, the flotation performance of coarse particles is often poor.

In the flotation separation of fine particles, the small size of the mineral particles reduces the likelihood of collision with bubbles. Furthermore, because fine particles are extremely light, when they do collide with bubbles, they struggle to overcome the resistance of the hydration layer between the particle and the bubble, making it difficult for them to effectively adhere to the bubble surface.

The particle size of coarse individual minerals must be controlled below the upper limit for mineral flotation. Currently, the upper limit for the flotation particle size of sulfide minerals is typically 0.25–0.3 mm; for native sulfur, it is 0.5–1 mm; and for coal, it is 1–2 mm. Furthermore, the generation of excessive slime should be avoided as much as possible. When the flotation particle size is less than 0.01 mm, the flotation performance indicators will deteriorate significantly.

The optimal grinding fineness must be determined through testing and evaluated comprehensively in conjunction with actual production data. For certain specific ores, a staged grinding and separation process is often employed to prevent overgrinding of the ore, thereby ensuring that ore particles that have achieved single-particle liberation can be promptly recovered.

2. Excessive Ore Slurry

If the froth machine contains much ore slurry, it will bring a series of adverse effects on the mineral processing. The main influences are as follows:

• Easy to mix in the foam product, so that the concentrate grade is reduced.
• Easy to cover the coarse-grained surface, affecting the flotation of coarse particles.
• Adsorption of a large number of agents increases drug consumption.
• The pulp is sticky, and the aeration conditions have deteriorated.

3. Flotation Reagent

The type and quantity of the agent added during the flotation process, the dosing place, and the dosing method are collectively referred to as the drug system, also known as the prescription. It has a major impact on flotation indicators.

Di dalam ore dressing, it is necessary to pass the ore selectivity test in order to determine the type and quantity of the agent, and in practice, the number, location, and mode of dosing should be constantly revised and improved.

4. Balanced Aeration & Mixing

In addition to oxygen, nitrogen, and inert gases, there are carbon dioxide and water vapor in the air.
The gas has a selective effect on the surface of the mineral; oxygen is the most important factor affecting the surface of minerals. Oxygen is beneficial to the hydrophobicity of sulphide ores/ sulfine flotation; however, if the action time is too long, the mineral surface will return to hydrophilicity. When the gas adsorption conditions are appropriate, the mineral surface will be drained, and the flotation mineral processing can be done even without a flotation agent. The Galena mine can only float up with the action of xanthate through the initial action of oxygen.

Stirring the slurry can promote the suspension of the ore particles and evenly disperse them in the tank, thus promoting the good dispersion of the air and making it evenly distributed in the tank, further promoting the enhanced dissolution of air in the high-pressure area of the tank, and strengthening the precipitation in the low-pressure area.

Enhanced aeration and agitation are advantageous for flotation separation, but not excessively, as excessive aeration and agitation can have the following disadvantages:

• Promoted the merger of bubbles
• Reduced concentrate quality
• Increased power consumption
• Increased wear of various parts of the flotation machine
• The volume of the slurry in the tank is reduced (this is because the volume of the tank is increased by the portion occupied by the bubble)
• Excessive agitation may also cause the ore particles attached to the bubbles to fall off.
  The optimum amount of aeration and agitation in production should be determined by experimentation, depending on the type and structural characteristics of the flotation machine.

Inflation and agitation are carried out simultaneously in the mesin flotasi. Strengthening them is beneficial to increase the flotation index, but if it is determined too much, it will cause shortcomings such as bubble merger, degraded quality, increased electric energy consumption, and mechanical wear. Therefore, aeration and agitation must be appropriate.

5. Slurry Concentration

Konsentrasi bubur dapat mempengaruhi indikator teknis dan ekonomi berikut ini:

• Tingkat pemulihan. Apabila konsentrasi bubur kecil, tingkat pemulihan rendah. Ketika konsentrasi bubur meningkat, tingkat pemulihan juga meningkat, tetapi tingkat pemulihan melebihi batas. Alasan utamanya adalah konsentrasinya terlalu tinggi, yang merusak kondisi aerasi mesin flotasi.
• Kualitas konsentrat. Aturan umumnya adalah bahwa kualitas konsentrat lebih tinggi pada pengapungan bubur yang lebih ramping, dan kualitas konsentrat berkurang pada pengapungan bubur yang lebih kaya.
• Konsumsi obat-obatan. Ketika bubur lebih tebal, jumlah pengolahan per ton bijih lebih sedikit, dan ketika konsentrasi bubur lebih tipis, jumlah pengolahan per ton bijih meningkat.
• The kapasitas produksi of the flotation equipment. As the concentration of the slurry increases, the production capacity of the froth flotation machine, calculated according to the treatment amount, also increases.
• Konsumsi air dan listrik. Semakin tebal pulp, semakin kecil konsumsi air dan listrik per ton bijih yang diproses.

Singkatnya, ketika konsentrasi bubur kental, maka hal ini bermanfaat untuk proses flotasi. Namun, jika bubur dan gelembung tidak mengalir dengan bebas, aerasi akan memburuk, sehingga mengurangi kualitas dan pemulihan. Dalam hal ini, berbagai bagian bijih flotasi harus menentukan konsentrasi bubur yang sesuai dengan sifat bijih dan persyaratan teknis yang relevan.

6. Process Conditions: Pulp Density, Flotation Conditions & Ore Properties

The most suitable ore pulp concentration during the flotation process is related to the ore property and the flotation processing conditions. The general rules flow as follows:

• Kepadatan Pulp. The mineral with a large flotation density uses a thicker slurry, while the mineral with a small flotation density uses a thinner slurry. Flotation of coarse-grained materials with thicker slurry, and flotation of fine-grained and muddy materials with thinner slurry.
• Nilai PH Pulp. The pH of the pulp refers to the concentration of OH– and H+ in the slurry, which is generally expressed by the PH value. Various minerals have a “floating” and “non-floating” pH when using different flotation agents for flotation. The pH of the critical pH. By controlling the critical pH, it is possible to control the effective sorting of various minerals. Therefore, controlling the pH value of the slurry is one of the important measures to control the flotation process.
• Waktu Flotasi. The flotation time directly affects the quality of the indicator. The time is too long, the grade of the concentrate is reduced; the time is too short, and the grade of the tailings is increased. Therefore, the flotation time required for various Minerals must be determined by experimentation.
• Kualitas Air. Floating water should not contain a large number of suspended particulates, nor can it contain soluble substances and various microorganisms that may interact with minerals or flotation reagents. This problem should be especially noticeable when using backwater, pit water, and lake water.
• Suhu Pulp. Flotation is generally carried out at room temperature, but sometimes it is necessary to warm the slurry to obtain a good sorting effect. Whether or not it needs to be determined according to the actual situation. If it is heated, it is best to adapt to local conditions and use waste heat and exhaust gas as much as possible.

7. Pulp Quality

The main effects of pulp quality score on the froth flotation process in metallurgy are as follows:

• Tingkat pemulihan. Within a certain range, when the pulp mass fraction is low, the recovery rate is low; as the pulp mass fraction is increased, the recovery rate is correspondingly increased. However, the mass fraction of the slurry should not be too large. If it is too large, the flotation machine is difficult to inflate normally in the slurry, which in turn reduces the recovery rate.
• Tingkat konsentrat. Aturan umumnya adalah bahwa kadar konsentrat akan lebih tinggi ketika flotasi bijih dilakukan dalam lumpur yang lebih ramping, sementara kadar konsentrat berkurang ketika diapungkan dalam lumpur yang lebih kental.
• Dosis agen. The flotation agent should maintain a certain mass fraction in the pulp to have a good flotation effect. When the pulp is thicker, the mass fraction of the medicament is correspondingly increased; that is, the required medicament mass fraction can be achieved with fewer chemicals, and the amount of medicament per ton of ore is correspondingly reduced. Conversely, when the pulp is thinner, the amount of the agent increases.

Custom Flotation Solutions from JXSC

For optimal flotation performance, each factor must be carefully controlled through continuous testing and process adjustment. Proper equipment selection and operation are equally crucial for achieving maximum mineral recovery and concentrate quality.