Biomasse et biocarburants liquides : Différence entre versions

Contexte

Les résidus de biomasse peuvent également être convertis en diverses formes de combustibles non solides. Ces combustibles sont considérés comme des biogaz et biocarburants liquides. Le but de ce processus de conversion est d'améliorer la qualité, l'énergie spécifique du contenu, le transport, etc., de la source de la biomasse brute ou pour capter les gaz qui sont produits naturellement car la biomasse est micro biologiquement dégradable ou lorsque la biomasse est partiellement brûlée. Le biogaz est un carburant souvent utilisé pour la cuisson et l'éclairage dans un certain nombre de pays, tandis qu'un facteur important de motivation dans le développement des biocarburants liquides était la volonté de remplacer les combustibles pétroliers. Dans cette fiche nous allons examiner quelques-uns de ces combustibles, leurs applications et les technologies de conversion utilisées pour les calculer.

En Europe et aux États-Unis, ainsi que dans plusieurs pays en développement, il y a un mouvement vers des cultures énergétiques spécifiquement pour la production de la biomasse comme combustible. Le potentiel de production d'énergie à partir de biomasse à travers le monde est énorme et les combustibles fossiles deviennent plus rares et plus coûteux, comme les niveaux d'émissions de carbone sont de plus en plus préoccupants et que les gens réalisent les avantages d'élaborer des options d'approvisionnement énergétique intégrées, puis la biomasse pourrait commencer à réaliser son plein potentiel en tant que source d'énergie.

Biogaz

Le biogaz est produit au moyen d'un processus appelé digestion anaérobie. C'est un processus par lequel la matière organique est décomposée par l'activité microbiologique et, comme son nom l'indique, il s'agit d'un processus qui se déroule en l'absence d'air. C'est un phénomène qui se produit naturellement au fond des étangs et des marais et donne naissance au gaz des marais ou au méthane, qui est un gaz combustible.

Il existe deux technologies communes pour obtenir du biogaz, la première (qui est plus répandue) est la fermentation des déchets d'origine humaine et animale dans des digesteurs spécialement conçus. La seconde est une technologie développée plus récemment pour capturer le méthane des sites d'enfouissement de déchets municipaux. L'ampleur de simples installations de biogaz peut varier d'un système allant d'une petite maison aux grandes installations commerciales de plusieurs milliers de mètres cubes.

Avantages de la digestion des déchets animaux et humains:

• la production de méthane pour une utilisation en tant que combustible. Les déchets qui ont une haute teneur en éléments nutritifs deviennent un engrais idéal, dans certains cas, cet engrais est le principal produit de la digestion et le biogaz est simplement un sous-produit. Lors du processus de digestion, les bactéries sont éliminées, ce qui est un grand avantage pour la santé environnementale.

Deux conceptions simples populaires de digesteur ont été développées; le digesteur chinois à dôme fixe et le digesteur biogaz indien à couvercle flottant (illustré dans les figures 1 et 2). Le processus de digestion est le même dans les deux digesteurs, mais la méthode de collecte des gaz est différente. Dans le type au couvercle flottant, le couvercle étanche à l'eau du digesteur est capable de se soulever lorsque le gaz est produit et agit en tant que chambre de stockage, tandis que le type à dôme fixe a une capacité de stockage de gaz plus faible et nécessite une bonne étanchéité pour empêcher toute fuite de gaz. Tous deux ont été conçus pour une utilisation avec des déchets d'animaux ou de crottes.

Les déchets sont introduits dans le digesteur par le conduit d'admission et soumis à la digestion dans la chambre. La température du processus est assez critique - des bactéries productrices de méthane fonctionnent plus efficacement à des températures entre 30 - 40°C ou 50 - 60°C. Lors de climats plus froids, de la chaleur peut être ajoutée à la chambre afin d'encourager les bactéries à mener à bien leur fonction. Le produit est un mélange de méthane et de dioxyde de carbone, typiquement dans un rapport de 6:04. Le temps de digestion varie de quelques semaines à quelques mois selon la charge et la température de digestion. La pâte résiduelle est éliminée à la sortie et peut être utilisée comme engrais.

Le biogaz a une variété d'applications. Le tableau 1 ci-dessous montre quelques applications typiques et pour un mètre cube de biogaz.

Les digesteurs biogaz à petites échelles fournissent habituellement des combustibles pour l'éclairage domestique et la cuisine.

Table 1: some biogas equivalents

Source: adapted from Kristoferson, 1991.

Some countries have initiated large-scale biogas programmes, Tanzania being an example. The Tanzanian model is based on integrated resource recovery from municipal and industrial waste for grid-based electricity and fertiliser production.

Biomass gasification

The process of biomass gasification is distinctly different form that of biogas production. Gasification is the process by which solid biomass materials are broken down using heat to produce a combustible gas, commonly known as producer gas. Common feedstocks for combustion include wood, charcoal, rice husks and coconut shells.

The biomass gasification plant consists of a reactor, similar to a simple stove, into which the solid biomass fuel is fed. The supply of air to the fuel is, however, carefully controlled to allow only partial combustion of the fuel to take place. During this process gases are given off which are captured and can be used as a fuel gas. Several combustible gases are given off - hydrogen, carbon monoxide and methane - as well as carbon dioxide and nitrogen.

Two reactor types exist; the fluidised bed reactor, which is used with large-scale gasification system, and the fixed bed reactor, which is employed for small-scale producer gas systems. There are three varieties of fixed bed reactor; updraft, downdraft and crossdraft. Each reactor type produces a different ratio of gases at different temperatures and with a differing level of cleanliness.

The gas has several applications. It can be used directly in a burner to provide process heat or it can be used in internal combustion engines, but requires cleaning and cooling for this application. Plant ratings for small-scale power output can range from several kilowatts up to several hundred kilowatts and for heat production the output can be several megawatts. System efficiencies vary considerably depending on fuel, reactor type and application. Producer gas is commonly used for commercial cooking applications.

The small-scale gasifier technology is reasonably simple and cheap and can be manufactured locally, although care should be taken to ensure safety standards are maintained as carbon monoxide, which is produced during combustion, is a toxic gas. In China, a downdraft reactor design has been in production since the 1960's which uses rice husks as feedstock and hundreds of these systems are in use. They have also been installed in Mali, Surinam and India (Stassen 1995). During the Second World War, when fuel supplies were in short supply, millions of vehicles in Europe were adapted to run on producer gas, and today in countries such as Brazil and the Philippines gasifiers are commercially available for a variety of applications.

Liquid biofuels

Liquid biofuels, as their name suggests, are fuels derived from biomass and processed to produce a combustible liquid fuel. There are two main categories:

alcohol fuels - these include ethanol and methanol vegetable oils - derived from plant seeds, such as sunflower, sesame, linseed and oilseed rape.

Ethanol is the most widely used liquid biofuel. It is an alcohol and is fermented from sugars, starches or from cellulosic biomass. Most commercial production of ethanol is from sugar cane or sugar beet, as starches and cellulosic biomass usually require expensive pretreatment. It is used as a renewable energy fuel source as well as being used for manufacture of cosmetics, pharmaceuticals and also for the production of alcoholic beverages.

Source: Goldemberg et al, Renewable Energy, Sources for Fuels and Electricity, 1993

Methanol is produced by a process of chemical conversion. It can be produced from any biomass with a moisture content of less than 60%; potential feedstocks include forest and agricultural residues, wood and various energy crops. As with ethanol it can either be blended with gasoline to improve the octane rating of the fuel or used in its neat form. Both ethanol and methanol are often preferred fuels for racing cars.

Vegetable oils

A further method of extracting energy from biomass is the production of vegetable oils as a fuel known as biodiesel. The process of oil extraction is carried out the same way as for extraction of edible oil from plants. There are many crops grown in rural areas of the developing world which are suitable for oil production - sunflower, coconut, cotton seed, palm, rapeseed, soy bean, peanut, hemp and more. Sunflower oil, for example, has an energy content about 85% that of diesel fuel.

There are two well-established technologies for oil extraction:

The simple screw press, which is a device for physically extracting the oil from the plant - this technology is well suited to small-scale production of oil as fuel or as foodstuff in rural areas. The press can be motorised or hand-operated. Solvent extraction is a chemical process which requires large, sophisticated equipment. This method is more efficient - that is, it extracts a greater percentage of the oil from the plant - but is less suited to rural applications.

The oil, as well as being used for lighting and heating, can be used as a fuel in internal combustion engines.

Biodiesel production is not complex and can be done on a small scale. The vegetable oil is converted to a useable fuel by adding ethanol or methanol alcohol along with a catalyst to improve the reaction. Small amounts of potassium hydroxide or sodium hydroxide (commonly called lye or caustic soda, which is used in soapmaking) are used as the catalyst material. Glycerine separates out as the reaction takes place and sinks to the bottom of the container. This removes the component that gums up the engine so that a standard diesel engine can be used. The glycerine can be used as a degreasing soap or refined to make other products.

Present status

Small-scale biogas production in rural areas is now a well-established technology, particularly in countries such as China and India. At the end of 1993, about five and a quarter million farmer households had biogas digesters, with an annual production of approximately 1.2 billion cubic metres of methane, as well as 3500 kW installed capacity of biogas fuelled electricity plant.

In India, there has been widespread development and dissemination of gasification technology to meet a variety of rural energy needs - for example, irrigation pumping and village electrification.

Ethanol production programmes have been initiated in several developing countries. The success of the Brazilian programme is mentioned earlier in this technical brief while in Zimbabwe for example, an annual production of about 40 million litres has been possible since 1983, using locally manufactured equipment.

Biomass energy and the environment

There are two areas of environmental concern when considering using biomass as a form of energy. Firstly, there is the issue of land degradation and deforestation. This concern can be addressed by proper management of sustainable energy crops. Although much of the biomass requirement for energy production can be met through utilising residues from the food industry, from agriculture or from commercial activity, careful planning of energy cropping is required to prevent undue stress on the environment.

With the recent global call to reduce carbon dioxide emissions, there is a strong case for promoting the use of sustainable biomass-to-energy technologies worldwide. Using modern technology, enormous reductions can be made in carbon dioxide emissions, particularly if liquid biofuels are used to replace their fossil-based equivalents. In fact, if biomass energy production is done on a sustainable basis, there is little net carbon dioxide addition to the environment.

There are other environmental concerns related to each fuel that need to be kept in mind, such as toxic emissions and production of tars and soots.

Local manufacture and involvement

Many biomass conversion technologies for rural applications are easily manufactured by local artisans or by small and medium sized engineering workshops. In Zimbabwe, locally made equipment for large scale ethanol production has led to the lowest capital cost per litre for any ethanol plant in the world.

In China and India biogas plants are produced in great numbers by local artisans. In Kenya, where biogas technology is still in its early stages of dissemination, local manufacturers have been quick to realise the potential and get involved with the production of biogas plants.

Dissemination

Kenya relies on imported petroleum to meet 75% of its commercial energy needs. In 1980, in an effort to reduce this high level of dependence on an externally controlled fuel source, the Kenyan government set up the Special Energy Programme (SEP). One aspect of the programme was the introduction and dissemination of biogas plant technology. After a poor start working with educational institutions, the programme turned to local artisans and commercial outlets working in the private sector. Hands-on training was given to masons and plumbers and private traders were encouraged to manufacture and stock appliances such as cookers and lights. By 1995, the number of plants installed in Kenya was estimated to be 880.

Ravindranath, N. H. and Hall, D. O., Biomass, Energy and the Environment: A Developing Country Perspective from India. Oxford University Press, 1995.

Karekezi, S. and Ranja, T., Renewable Energy Technologies in Africa. AFREPEN, 1997.

Kristoferson L. A., and Bokalders V., Renewable Energy Technologies - their application in developing countries. ITDG Publishing, 1991.

Johansen, T.B. et al, Renewable Energy Sources for Fuels and Electricity. Island Press, Washington D.C., 1993.

Gunnerson C. G. and Stuckey D. C., Anaerobic Digestion - Principles and Practices for Biogas Systems. World Bank Technical Paper No 49, The World Bank, 1986.

Gitonga, Stephen, Biogas Promotion in Kenya. Intermediate Technology Kenya, 1997.

Stassen, H.E., Small-scale biomass gasifiers for heat and power: a global review. World Bank technical paper no. 296, Energy Series 1995.

Quaak, P., Knoef, H. and Stassen, H.E., Energy from biomass: a review of combustion and gasification technologies. World Bank technical paper no. 422, Energy Series 1999.

Anderson, T., Doig, A., Rees, D. and Khennas, S., Rural Energy Services: A handbook for sustainable energy development. ITDG Publishing, 1999.

Tickell, J., Teickell, K., From the Fryer to the Fuel Tank: The Complete Guide to Using Vegetable Oil as an Alternative Fuel, Greenteach Publishing, 1999.

Pahl, Greg, Biodiesel: Growing a New Energy Economy. Chelsea Green Publishing, 2004 http://www.chelseagreen.com/2004/items/biodiesel.

This Howtopedia entry was derived from the Practical Action Technical Brief Biogas and Liquid Biofuels - Technical Brief.
To look at the original document follow this link: http://practicalaction.org/?id=energy

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