Harnessing the Power of Biogas Energy

This content is sponsored by JWC Environmental. Sponsored content is authorized by the client and does not necessarily reflect the views of COLE Publishing. View our privacy policy.
Harnessing the Power of Biogas Energy

Anaerobic digestion offers an efficient, cost-effective process for green energy development, while also providing a sustainable solution for the disposal of animal byproducts. In a typical biogas processing operation, manure, wastewater solids, agricultural residues and food scraps are delivered to a digester system. The process uses microbes to break down the organic material through a fermentation process under controlled conditions, resulting in clean biogas and digested material. That digested material is then used to make fertilizer, compost, soil amendments or animal bedding. The raw biogas is further processed and water, carbon dioxide and other trace compounds are removed, leaving mostly methane and other trace gasses. The processed biogas is then distributed and used for producing electricity, heat and fuel, or injected into natural gas pipelines. Biogas provides a clean, repeatable source for energy and fuel, while also making use of organic materials that might otherwise end up in a landfill.

Biogas feedstock can also include tough, large pieces of inorganic debris, like metals and plastics that find their way into the organic mixture. This material, if left uninhibited, can clog the pumps and pipelines within the digester and cause the system to break down. Operators have to dismantle the pumps and rebuild them, a time-consuming and costly process. In 2013, a biogas production facility in Catalonia, Spain, was experiencing these very problems and worked with Protech Continental, the exclusive JWC International distributor in Spain, to devise a long-term solution that would keep the system running smoothly.

The Spanish biogas facility relies on feedstock from local industrial (dewatered sludges) and agricultural (manure and slurry) sources to produce biogas, which they then use to generate electrical power. In the process, the dewatered sludge is fed into the system, along with the slurry and cow manure, typically with 8-12% dry solids (DS) — a typical feedstock combination in the Spanish biogas market. Dewatered sludge at 25% DS are mixed with quantities of manure at 5-8% DS to give a resulting mixture of around 13% DS, which can be pumped and still has a high organic content, rather than diluting the thick sludge.

The liquid manure is used to dilute the dewatered sludge to reduce the viscosity to around 3,000 to 5,000 cps, which is similar in viscosity to syrup or molasses. This ensures it is easily pumped and still able to sustain the process without diluting the organic content available for digestion.

The customer found that the imported loads included many inorganic problem solids, including bolts and scrap metal, plastics, tools and ropes. The plant was designed with a chopper pump to deal with solids but the inorganic solids in the feedstock caused significant problems for the in-line chopper pump. Eventually, the chopper pump was replaced with a progressive cavity pump supplied by Protech.

The progressive cavity pump performed exceptionally well, sucking the slurry up and out of the mixing tank and into the process. However, the tough inorganic solids eventually caused undue wear and weekly maintenance issues, resulting in the first stator replacement after just six months of operation.

Protech worked with the engineers on a more durable, reliable solution for the tough waste, and suggested an in-line Muffin Monster. The dual cutter stacks are equipped with exceptionally sharp, hardened-steel teeth, ideal for slicing through incredibly tough debris.

Since incorporating the Muffin Monster, the system hasn’t experienced any downtime due to material clogging, and the maintenance crew was able to wait 19 months to replace the stator.

By installing the progressive cavity pump with the Muffin Monster for protection, the customer gained operational hours due to reduced maintenance, spare parts savings, and also reduced downtime and failures in the plant. The addition of the grinder is the only upgrade or addition to the facility since it was built, and the grinder has extended the stator repair interval, offering savings of approximately €500 ($656 USD) per stator change, and has further increased the maintenance and repair intervals to keep the plant operating at peak performance.

For more information on the Muffin Monster, visit www.jwce.com.


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.