Biogas? China size it

Conversion to a symmetrical or parallel system for our world’s electricity generation will require a combination of small, locally-generated power supplies, coupled with individual home generation, in addition to the regular power grid supply. Conversion to a new world, not in geography, but in power generation will need to be developed as a hybrid of generation sources comprised of: Concentrating Solar Power (CSP), Hydroelectric, Geothermal, Wind, PV Panel, Tidal Current and Magnetic Linear Generator Buoys, plus Bio-Mass and Biogas in addition to coal and natural gas.

A new world is emerging that will require the recycling of waste that has not previously been recycled - on a massive worldwide scale. Not plastic or glass, but our waste: animal waste and food waste, turning it into a high end useable commodity.

The topic of using fecal matter as an energy source ranges from taboo in some societies to wide acceptance and utilisation in others. Let’s see what China’s National Development & Reform Commission has on the books in the next few years for biogas.

In China alone there are a 1.3 billion people with just as many livestock, poultry and garbage dumps all providing methane feedstock daily. It’s hard for China to sidestep the idea of turning something that was once discarded into a commodity for sale, and more importantly into electricity. China plans to have an installed capacity of bio-energy projects reaching 5.5 million kW by 2010, but jumping to 30 million kW by 2020, a 600 per cent increase in the next 11 years.

Biogas is a combustible mixture of gases produced by micro-organisms when livestock manure and other biological wastes are allowed to ferment in the absence of air in closed containers.

The major constituents of biogas are methane (CH4, 60 per cent), carbon dioxide (CO2, 35 per cent), small amounts of water vapour, hydrogen sulphide (H2S), carbon monoxide (CO), and nitrogen (N2).

Biogas is mainly used as fuel, like natural gas, while the digested mixture of liquids and solids “bio-slurry” and “bio-sludge” are mainly used as organic fertiliser for crops. Chinese companies are now finding numerous other uses for biogas, bio-slurry and bio-sludge in China. Which touches on an important aspect of Peak Oil: the reduction in fertiliser production along with rising farming costs, due to increased fertiliser prices, that must be passed along as higher food prices.

You could open Pandora’s Box when explaining how oil dependant the farming, transport and processed food production industries are. Increased transportation costs to move food stuffs from field, to factory to your plate. Fertiliser and pesticide rely on natural gas and oil based chemicals for production, and farm machinery is run on liquid fossil fuels. The simplest equation is: higher crude oil prices = higher food costs.

China began using biogas digesters in earnest in 1958 in a campaign to exploit the multiple functions of biogas production, which solved the problem of the disposal of manure and improved hygiene.

During the late 1970s and early 1980s the Chinese government realised the value of this natural resource in rural areas and this was the first important step in the modernisation of its agriculture. Six million digesters were set up in China, which became the biogas capitol of the world incorporating the “China Dome” digester which is still used to the present day, especially for small-scale domestic use.

China’s 2003-2010 National Rural Biogas Construction Plan is to increase biogas-using households by a further 31 million to a total of 50 million, so the rate of use would reach 20 per cent of total rural households.

By the end of 2006, the total number of families that use biogas reached 22 million, with a total annual biogas production of about 8.5 billion cubic meters. There were biogas pits built for 22 million households in rural areas, and more than 5,200 large and mid-sized biogas projects based around livestock and poultry farms. The typical eight cubic meter biogas pits are able to provide 80 per cent of the cooking energy for a four-member family according to The Energy and Zoology Division inside the Ministry of Agriculture. By 2020, about 300 million rural people will use biogas as their main fuel.

During the current 10th Five Year Plan, China is developing 2,200 power grid biogas engineering projects for wastes from intensive animal husbandry and poultry, treating more than 60 million tonnes of manure a year, that’s in addition to the 137,000 installed digesters to treat sewage.

According to The Chinese Academy of Sciences and Geography, the total annual production of manure and night soil could theoretically generate about 130 billion m3 of methane, equivalent to 93 million tonnes of coal; and 80 per cent of industrial wastewater can also be used to produce methane. The number of large scale grid power plants are planned to increase to 30,000 by 2030, a 15-fold increase.

As the idea of cleaning up the environment starts to take traction in China, dealing with sludge from urban and industrial wastewater treatment that has traditionally been dumped into landfills, oceans and waterways is taking centre stage with a catchy campaign “Recycle Waste into a Resource”. The Chinese central government is showing great interest in medium and large scale biogas plants and integrated agricultural and agro industrial biomass with waste handling plants to reduce water pollution.

To facilitate the usage of biogas the government set up biogas technical training courses in Shanxi Province and in 2005 trained 6,000 farmers, 4,000 of which gained National Biogas Professional Technician Certificate. The Ministry of Agriculture which administers The Chengdu Biogas Scientific Research Institute (BIOMA) also operates an international training and research center in Chengdu, Sichuan Province.

Farmers from Yunnan Province that graduated from the course are experimenting with a "four-in-one" biogas plant that incorporates a pigpen and a household latrine to provide feedstock, then uses methane to heat a greenhouse for growing vegetables and raises carbon dioxide within the greenhouse to boost plant yield.

Biogas feedstock programs throughout China are just beginning to utilise industry waste from other sources such as alcohol manufacturers and paper mills. Tianguan Alcohol Factory, which consumes two million tonnes of shop worn grains a year to produce denatured alcohol, is now recycling the dregs of the distillery to produce biogas in a 30,000 m3 digester, supplying more than 20,000 households or 20 per cent of Nanyang city’s population.

Hongzhi Alcohol Corporation located in Mianzhu, Sichuan Province which is the largest alcohol factory in south-western China, uses its industrial organic wastewater, sewage and dregs to produce biogas. The city of Mianzhu treats 98 per cent of municipal sewage including wastewater from hospitals through digesters with a total capacity of 10,000 m3.

Recently, Chenming Paper Co. which generates 300 tons of sludge a day is adding its own start up biogas program using pulp wastes. The same goes for intensive animal husbandry on many large or medium size livestock and poultry farms in the suburbs of cities.

China’s power generation is starting to morph into local energy generation for local residents from local industry using local feedstock, which is a model we should get used to in a world of high energy prices: Local production, Local consumption.

As our globalised “distant point of manufacture”, “long delivery chain” lifestyle changes year upon year with declining crude oil availability, we, as a world, will need to find crude oil substitutes to supply base chemicals for industrial and manufacture processes. Using biogas directly for cooking or co-generation of electricity and heat is especially feasible when the biogas is used at or near the site of generation.

Biogas methane can also be used to make methanol, an organic solvent and an important chemical for producing formaldehyde, chloromethane, organic glass, and compound fibre. Good quality fertiliser and the electricity generated are additional bonuses.

Finally, biogas can be used to prolong storage of fruit and grain. An atmosphere of methane and carbon dioxide inhibits metabolism, thereby reducing the formation of ethylene in fruits and grains prolonging storage time and the same atmosphere kills harmful insects, mould, and bacteria that cause diseases.

My minds eye sees a future where food storage will be in local communities, The just-in-time delivery system will encounter problems as fuel becomes more expensive and disposable income is reduced. I envision a return to a bulk delivery system of dry goods, which will be weekly or bi weekly, and local communities will store their own grain and bulk food utilising biogas to keep pests and rodents out of the food supply.

The small shipments we are used to today will need to be restructured into a bulk delivery system. Foods from supermarkets packed in small individual boxes, bags or wrapped in plastic will have present problems for manufacture and delivery.

This will give biogas an edge by offering solutions to two probable side effects of continuing rising oil prices: food storage and fertiliser.