Multi-media filters are widely used in water treatment, petrochemical, food processing, and other fields as a type of filtration equipment. Their core function is to remove impurities from liquids through multiple layers of different materials to achieve the purpose of purification and clarification. However, there are many factors that affect the filtration effect of
multi-media filters. Understanding and controlling these factors can significantly enhance the filtration performance of the equipment. The following are the main factors affecting the filtration effect of multi-media filters and their interrelationships.
The impact of temperature on liquid viscosity is directly related to filtration efficiency. Generally speaking, the viscosity of a liquid increases as the temperature decreases, and the greater the viscosity, the slower the filtration process. Therefore, appropriately raising the temperature of the liquid during the filtration process can reduce viscosity and thus increase filtration speed. However, it needs to be handled with caution that excessively high temperatures may lead to the oxidation of some liquids (such as wool oil), damaging their physical and chemical properties. Therefore, in the filtration process of wool oil, the temperature is usually controlled not to exceed 70 degrees Celsius to balance the relationship between reducing viscosity and preventing oxidation.
Working pressure is also an important factor affecting filtration effects. For liquids containing incompressible impurities, increasing the working pressure can usually improve filtration speed, as a greater pressure can force liquids to pass through the filter medium more quickly. However, if the liquid contains colloidal substances, when the pressure increases, the pores in the filter cake will decrease, causing an increase in filtration resistance, and thus reducing filtration speed. Therefore, the setting of pressure needs to be optimized according to the properties of the liquid to ensure the best filtration efficiency.
The concentration of the liquid has a direct impact on the filtration process. High-concentration liquids often contain more suspended solids, which can lead to the accumulation of filter residue in intermittent production, shortening the filtration period and affecting production. On the contrary, in continuous operation systems, high-concentration liquids can form a more uniform filter cake, which is easier to clean, and thus has less impact on production efficiency. Therefore, the concentration control strategy under different operating modes should be different to adapt to production needs.
The selection of filtration media is key to determining the filtration effect. Multi-media filters can use a variety of filtration materials, such as quartz sand, anthracite coal, activated carbon, etc. The particle size, shape, porosity, thickness, and surface properties of the medium directly affect the filtration effect.
1. Particle Size
The smaller the particle size, the higher the filtration efficiency, but the head loss also increases more quickly. Therefore, in the filtration of small filter materials, the appropriate selection of particle size is crucial for balancing filtration efficiency and head loss.
The specific surface area of angular filter materials is greater than that of spherical filter materials, so the filtration efficiency of angular filter materials is higher under the same volume. However, the porosity of angular filter materials is usually also larger, which provides a larger space for impurities and a longer filtration time, but is also prone to the penetration of suspended solids.
A larger porosity helps to extend the filtration period but may reduce filtration accuracy. Conversely, a smaller porosity will improve filtration accuracy but increase head loss.
The thicker the filter layer, the better the filtration effect, the clearer the filtrate, and the longer the operation period. However, an overly thick filter layer may increase the system's pressure drop, affecting overall efficiency.
The surface charge properties of filter materials affect the adsorption and coagulation of suspended particles. By adjusting the pH value or adding electrolytes, the electrostatic potential of the filter material surface can be changed, thereby optimizing the filtration effect.
The properties of suspended solids have a significant impact on filtration efficiency, including particle size, shape, density, and surface properties.
1. Particle Size
Larger suspended particles are easier to remove by filtration, so adding coagulants to the raw water to generate flocs of appropriate particle size can significantly improve filtration efficiency.
Angular suspended particles, due to their larger specific surface area, are usually more efficiently removed than spherical particles.
Although the density of particles affects filtration efficiency through sedimentation, inertia, and Brownian motion, this impact is relatively small, so it does not need to be overly concerned in actual operations.
As the concentration of raw water increases, filtration efficiency will decrease because high-concentration suspended solids are more likely to penetrate the filter material, increasing head loss. Therefore, controlling the concentration of raw water is crucial for maintaining efficient filtration.
Temperature has a significant impact on the density and viscosity of suspended solids, thereby affecting filtration effects through sedimentation and adhesion mechanisms. Generally speaking, lower temperatures are not conducive to filtration effects, so appropriately increasing the temperature within the allowable range can help improve efficiency.
The surface charge characteristics of suspended solids affect their flocculation and filtration performance. In the coagulation filtration method, filtering after destabilizing the suspended solids with medication can significantly improve filtration effects, especially when the flocs have not yet fully formed.
In summary, the filtration effect of multi-media filters is influenced by a combination of factors such as temperature, pressure, concentration, filtration media, filter material characteristics, and the properties of suspended solids. By reasonably controlling and optimizing these factors, the performance and filtration effect of the filter can be significantly improved. In actual operations, understanding the interactions between various factors, adjusting operational parameters, and selecting suitable filtration media are key to ensuring the efficient operation of multi-media filters.