Many Water Resource Recovery Facilities (WRRF) -- formerly known as Wastewater Treatment Plants (WWTPs) --in Indiana already have effluent phosphorus limitations or are receiving them for the first time.
Chemical precipitation of phosphorus is commonly used to meet these effluent limits due to the relative ease of operation. Metal salts such as Alum (Aluminum Sulfate) or Ferric Chloride are metered into the process where the Aluminum or Iron ions bind soluble phosphorus allowing it to be settled out of the process.
While this process is widely used, there are other options available.
Here are a few frequently asked questions about the removal process known as EBPR, with answers.
Enhanced Biological Phosphorus Removal is a process in which the biology within the activated sludge system is manipulated so that microorganisms take more phosphorus into their cells than they normally would.
It should be noted that all activated sludge systems involve biological phosphorus removal; phosphorus is an essential element for life. The key to EBPR is getting microorganisms to take in more phosphorus than they need.
This is also known as luxury uptake.
This process reduces your chemical consumption. Utilizing EBPR will not eliminate the need for a chemical storage tank and metering pump, but it will reduce how much chemical you need to use. Some WRRFs have seen a 90% reduction in chemical consumption or more leading to:
In order to create the necessary conditions for EBPR, an anaerobic environment needs to proceed the aerobic environment. This is typically achieved by adding a new tank (anaerobic selector) to the process prior to aeration basins. As the tank is an anaerobic environment, no aeration is needed in this tank.
The tank does need to be mixed, so a submersible or floating mixer is often required. Screened and degritted wastewater is introduced into the anaerobic tank along with Return Activated Sludge.
These items have been presented in the sequential order they should be considered, starting with an evaluation of proper conditions. Every waste stream is different. Some WRRFs simply do not have an influent waste stream that is conducive for successful EBPR.
Start by collecting the right data. Your system designer may want to see the following information:
This data should help give you a good idea of how effective EBPR could be at your facility.
You can find published guidance regarding the ratio of cBOD5, COD, and VFAs to phosphorus. VFAs specifically are very important to the microorganisms that perform luxury uptake. Some treatment plants just don’t have the right influent waste to make EBPR worth the investment.
It is important to build a good data set. Don’t get discouraged by one bad sample. It’s also important to identify if diurnal or seasonal variations exist in your system.
It takes time to gather this information, so get started well before you need to make decisions regarding how to treat for phosphorus.
Still have questions about EBPR? Leave a comment below, or give me a call.