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Closed-loop concept could be future of sustainable animal farmsClosed-loop concept could be future of sustainable animal farms

Closed-loop dairy concept focuses on three main goals: producing bioenergy using dairy manure and treating wastewater and capturing greenhouse gases both via dairy manure-derived biochar.

January 24, 2017

5 Min Read
Closed-loop concept could be future of sustainable animal farms
Dr. Eunsung Kan stands in front of a dry-erase board used to explain his closed-loop dairy farm concept and use of biochar to filter wastewater and create electricity.Texas A&M AgriLife Extension Service photo by Adam Russell.

Dr. Eunsung Kan sees his concept of a closed-loop dairy farm — which reuses wastewater, emits zero waste and powers itself on manure — as the future of sustainable animal farming.

Kan, a Texas A&M AgriLife Research chemical and environmental engineer in Stephenville, Texas, said his concept could change the way dairies, swine and poultry farms deal with manure, wastewater and greenhouse gases while utilizing the waste to generate electricity.

Animal waste is a blessing and curse for dairies. Manure is sold to local farmers who need to infuse nutrients into the soil for crops and forage. However, tons of manure can also be logistically taxing as facilities keep up with the treatment and distribution of large quantities of environmentally problematic materials monitored by state and federal environmental regulators.

Farm operations have been implicated in higher-than-normal levels of nitrogen and phosphorous, antibiotics, heavy metals and hormones in surface and groundwater downstream from facilities. Manure is also a known contributor to greenhouse gas emissions, such as methane and carbon dioxide.

The U.S. Department of Agriculture's Natural Resources Conservation Service estimates that manure from a dairy milking 200 cows can produce as much nitrogen as is in the sewage from a community of 5,000-10,000 people.

Kan’s research would utilize existing technology such as biochar — a carbon material similar to charcoal created from animal manure and agricultural waste, such as corn stubble or rice straw — that would be used to filter solid waste and effluent. The biochar could be used as a slow-release fertilizer or converted via pyrolysis — the decomposition of organic material by heat — into energy to power the farm.

The closed-loop dairy concept focuses on three main goals: wastewater treatment using dairy manure-derived biochar, producing bioenergy using dairy manure and capturing greenhouse gases via adsorption onto dairy manure-derived biochar, Kan said.

Biochar has proved to provide a beneficial surface chemistry that can filter a wide range of contaminants, including nitrogen and phosphorous, he said. When the surface of biochar is modified with several methods in a lab, it has shown an ability to capture antibiotics, pesticides, hormones, heavy metals and other possible contaminants.

“The mission is the treatment and reuse of dairy wastewater and the conversion of dairy waste into energy to power the facility,” he said. “It focuses on providing a model for sustainable farming.”

Last year, Kan received a $1 million grant from the Texas A&M University Chancellor’s Research Initiative Fund to research the viability of the closed-loop dairy system. Before joining AgriLife Research, he also received about $400,000 in research grants from the Environmental Protection Agency, USDA and the U.S. Geologic Survey to research the concept’s potential to treat animal waste, control greenhouse gas emissions and convert manure to energy.

Conceptual system

The closed-loop dairy is a relatively simple concept, Kan said. Cows produce manure that, when mixed with remnants of local crops, can become a seemingly endless supply of filtering material, fertilizer and energy.

Columns filled with biochar would act as a water purification system that filters nitrogen, phosphorous and other contaminants from liquid as it passes through the material, Kan said.

“The affluent from the column would then be very low in nitrogen and phosphorous,” he said. “If we filter to low levels of nitrogen and phosphorus, it wouldn’t cause any environmental problem.”

The biochar used to filter nitrogen and phosphorous could then be used as slow-release fertilizer that provides needed nutrients to plants and would not wash away as runoff during heavy rains. In addition, biochar immobilized with photocatalysts would decompose toxic contaminants to harmless products when irradiated by exposure to ultraviolet light.

For instance, Kan’s study has shown that a biochar immobilized with photocatalysts completely degraded antibiotic and hormone compounds while effectively controlling pathogens. The potential for biochar’s use to filter wastewater goes beyond agriculture and could be applied at any wastewater treatment plant or even to filter contaminants in the injection water used for fracking in the petroleum industry.

For energy, dairy manure would be fed into a pyrolysis reactor on site that would use relatively low heat — 500-1,000°F — to create compressed hydrogen and carbon monoxide syngas that can be used to create electric power, Kan said. Excess electricity could be sold to local utility companies. The byproduct from pyrolysis of dairy manure is biochar.

“The principle is very simple,” Kan said. “The dairy would just need a different sized reactor to meet its scale of manure output and energy needs.”

Dr. Sergio Capareda, an AgriLife Research agricultural engineer in College Station, Texas, proved the pyrolytic conversion of dairy manure to syngas and biochar from his USDA-funded project, Kan said. Kan plans to advance this concept by biologically converting syngas to butanol and bio-jet fuel as alternative transportation fuels and developing biochar-based processes for wastewater treatment and greenhouse gas control.

Several other researchers and engineers within the Texas A&M system are collaborating with Kan, and interest in the concept is growing among public institutions and private companies.

Kan will produce a lab-scale version of the closed-loop dairy to determine the necessary scale for application and experimentation at the neighboring Southwest Regional Dairy Center in Stephenville, a privately owned working dairy operated by Tarleton State University that's used for educational purposes. He hopes to have a system, including the pyrolysis reactor, operating at the dairy within three to four years.

Kan said he believes the closed-loop system will prove to be a logistically and financially viable model for dairy producers to implement in the future. He expects his pilot project at the regional dairy to produce data that will draw more interest and investment from public institutions and private companies.

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