How Can You Ensure Your MBBR System Operates Efficiently?
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- publisher
- Kate
- Issue Time
- Mar 30,2024
Summary
The article details enhancing MBBR efficiency through biofilm optimization, covering formation stages, influencing factors, and improvement strategies.
The biofilm formation process typically includes the initial microbial adsorption, growth, and maturation stages. During this process, microbes adhere to the media in the MBBR reactor, forming a stable biofilm. Factors such as temperature, pH, dissolved oxygen, nutrient concentration (e.g., nitrogen, phosphorus), water flow rate, and the material and surface properties of the carriers can influence the speed and quality of biofilm formation.
1. Slow Biofilm Formation: Conditions like low temperatures, insufficient nutrients, and unsuitable pH values may lead to slow biofilm formation.
2. Biofilm Detachment: High flow rates, mechanical damage, or internal anoxia caused by overly thick biofilms can cause biofilm detachment.
Uneven Biofilm Thickness: Uneven water distribution or carrier aggregation can lead to uneven biofilm thickness, affecting treatment efficiency.
3. Biofilm Aging: Over time, biofilms may age and become less efficient, necessitating cleaning or replacement of the carriers to address this issue.
1. Inoculation Start-up
① Direct Inoculation: Adding active sludge or specific microbial strains directly to the MBBR system to accelerate biofilm formation.
② Indirect Inoculation: Introducing water-containing microbes into the MBBR system through circulation, using the existing microbial community to promote biofilm formation.