A Resource Hero: The Treatment Plant Operator

This content is sponsored by HUBER Technology. Sponsored content is authorized by the client and does not necessarily reflect the views of COLE Publishing. View our privacy policy.
A Resource Hero: The Treatment Plant Operator

Interested in Headworks?

Get Headworks articles, news and videos right in your inbox! Sign up now.

Headworks + Get Alerts

The metamorphosis of wastewater treatment plants into water resource recovery centers has sparked fascinating new insights and opportunities. Early on in these emerging WRRFs, the focus was directed to recovering usable water for irrigation purposes and the distribution of usable biosolids as a soil amendment. This low hanging fruit has propelled WWTPs firmly into the minds of the population as a viable solution to dwindling resources.

Energy costs to operate a WWTP are significant. The size of the facility and the use of advanced treatment techniques continue to add to the energy demand. The steady increase of the cost of conventional energy sources both in money and carbon-emission-concerns have created the drivers to look for sources of renewable and recovered energy to offset the operational demand.

Delivered energy to your door

Tremendous sources of energy get delivered directly to the WWTP by the sewer networks. One of the most potent sources of energy in the arriving wastewater is the biodegradable material which is captured and redirected to anaerobic digesters. The methane gas produced in the digestion process is used in cogeneration to drive microturbines which both generate electricity and harvest thermal energy for building heating and enhancing digestion. Energy creation from anaerobic digestion was so effective that additional sources of fats, oils and grease were sought out in the surrounding community to radically increase energy production from the digesters. The addition of FOG has enabled an increasing number of WWTPs to reach net zero energy goals, and more facilities are enabled to be a net producer of renewable energy.

Open for business

The closer we examine what is possible for resource recovery in the WWTP, the more opportunities emerge to generate revenue. More recently the idea of the circular economy has woven its way into the resource recovery discussion. The nexus of the circular economy and the WWTP is being explored. In the Scottish report “Water and the circular economy – Where is the greatest sustainable economic benefit for resource recovery in the watercycle?,” analysis has determined six resource areas, of which five have a state of readiness to create value for reclamation in the collected wastewater stream:

  1. The most significant potential lies in the recovery of energy from raw water and wastewater with heat pumps.
  2. Anaerobic digestion of wastewater can also generate a significant amount of resources, in particular methane, energy and CO2 savings.
  3. Organic solid waste, in addition to wastewater, can supplement anaerobic digestion.
  4. Recovery of biopolymers (polyhydroxyalkanoates, PHAs, polylactic acid, PLA).
  5. Recovery of inorganic materials.

Similarly, Amsterdam in the Netherlands is active with an initiative to recover resources in the context of a circular economy. They make an interesting observation: “The problem is not the availability of technology for resource recovery, but the lack of a planning and design methodology to identify and deploy the most sustainable solutions in a given context.”

In another article “The Risks and Mitigation of Plastics in Wastewater,” it was identified that the WWTP was both the cause and the cure to microplastics entering in the waterways. In that article, it was also pointed out that a majority of the microplastics were captured and found to be removed, mainly in the primary treatment zones via solids skimming and sludge settling processes. In both the Scottish and Dutch reports they targeted the solids settling zone as a key point for extracting additional resources such as biopolymers (PHA) and cellulose. It is an interesting intersection where, at the same point in the treatment process, the offending microplastics are collected in the primary sludge, so too is a source for a biodegradable plastic alternative using PHA. This blend of collection and repurposing is on track with the recommendations made in Part IV of the Ellen MacArthur Foundation report to the 2016 World Economic Forum calling for development and alternative sourcing of biodegradable plastics.

Sustainable solutions in a given context

Circling back to part of the quote from the Amsterdam group “…identify and deploy the most sustainable solutions in a given context,” optimizing or modifying a process can potentially reduce an energy load. Microsieving can be used both as an advanced primary technique to harvest and redirect recovered materials, as well as to provide a mechanism to lower energy loads deeper in the process. By applying a process intensification method of using microsieving technology as an advanced primary clarifier, a means of high-rate, controlled carbon diversion is opened up. Diverting carbon in primary sludge to anaerobic digesters can lower (by a third or more) the energy cost for aeration in the activated sludge basins by reducing BOD/COD loading. Microsieving for primary clarification can be controlled to allow for the return of appropriate organic nutrient levels required for biological nutrient reduction techniques to operate properly.

Historically for smaller plants, aerobic digestion processes were a practical design choice to accomplish the facility’s treatment objectives. With increases in energy costs, and rising costs of sludge disposal, alternative processes which reduce the energy required and minimize sludge disposal volumes are being explored. Cost-effective developments in anaerobic digestion technologies have opened the door for practical implementation in smaller facilities. With the addition of anaerobic digestion, sludge diverted from the advanced primary clarifier offsets the aeration cost for the biological oxidation processes, because this sludge has optimized energy potential for efficient and effective anaerobic digestion and subsequent energy generation. In “A Guide to Net-Zero Energy Solutions for WRRFs” (WE&RF ENER1C12), they indicate “Anaerobic digestion with combined heat and power was the most advantageous approach to energy recovery, reducing energy requirements by up to 35% at WRRFs that have anaerobic digestion.” Carbon diversion using chemically enhanced primary treatment or A-stage processes could help plants achieve energy neutrality.

It keeps getting better

As it becomes financially viable there are more resources to be extracted. Municipal wastewater contains an appreciable amount of cellulose (primarily toilet paper). One common use of recycled cellulose is building insulation. We also described the possibility of harvesting biopolymers for the creation of PHA biodegradable plastics. Practical techniques for struvite (phosphorous) precipitation are being introduced into the market.

The resource recovery facility consistently demonstrates the ability to be a front runner, leading the way in producing a sustainable example that is in step with the new circular economy. As these WRRF facilities continue to be created, it is clear that there are opportunities in the capture and harvest of valuable resources that were previously passed on to landfill or into the environment. Further, through process intensification approaches, it is also possible to accomplish these identified resource recovery objectives while still lowering the net energy required to operate. This accomplishes not only moving the needle for operating a WWTP from an expense to a revenue source, but it provides another notable contribution to reducing carbon loading in the environment.

The world is looking for courageous people and processes that are part of the solution and not part of the problem. As we all go about our daily work in the water profession, we can draw great satisfaction. The treatment plant operator is at the command of a powerful emerging resource generator. 

HUBER Technology Inc., based in Denver, North Carolina, is one of the country’s largest manufacturers of wastewater, sludge and grit handling equipment. HUBER offers multiple screening and filtration solutions for municipalities and numerous industrial wastewater and intake applications. For more information on any of HUBER’s product lines, please complete the form at www.AskHUBER.com.

Visit the HUBER Technology, Inc. Storefront


Comments on this site are submitted by users and are not endorsed by nor do they reflect the views or opinions of COLE Publishing, Inc. Comments are moderated before being posted.