Biodigesteur domestique/en : Différence entre versions

Étape 4 - Matter circuit - Bonding and sealing

If the blank assembly is satisfaying, we will now glue PVC components together :

• Mark each of the connectors on their junction, so that you can reassemble the system respecting alignements.
• Clean areas that will be glued.

• Bond with PVC glue.

• Let it dry.

Then we will test the sealing :

• Block temporarily the overflow outpur (for example with an air chamber and a hose clamp), screw the cap of the matter input part ("the mouth") and the draining plug.

• Put the system under pressure with a compressor flowing in the gas valve.

• Spray soapy water on the junctions. If bubles form, the sealing is not correct and the system has to be rebuild.

Étape 7 - Gas circuit - Digestor

In the digestor, bacterias will produce biomethane as they degradate the organic waste. In variable proportions, it is composed of :

• Methane (CH₄) 50 to 70%

• Carbon dioxyde (CO₂) 35 to 40%

• Hydrogen sulphide (H₂S) 1 à 3%

• Water vapor (H₂0) variable

There can be also traces of hydrogen, oxygen, carbon monoxyde, nitrogen, and other gases in very small quantities.

Étape 9 - Carbon dioxyde

Its proportion depends on the bacterian reactions, the temperature and the organic waste. CO₂ disturbs combustion, but does not prevent it.

The easiest is to wash the gas with water. Carbon dioxyde is very soluble (878 cm³/l at 20°C), unlike methane (34 cm³/l). This water carrying CO2 can be used for agriculture irrigation, or for algeas farming such as spirulina.

• At the digestor exit, after the valve, create a gas circuit bringing the gas in a bubbler-reservoir.

• The reservoir must be filled with water.

• The gas arrival pipe dives into the water.

• The gas output pipe in on the top of the reservoir.

• A draining plug at the bottom of the bubbler-reservoir with allow collection of water carrying CO₂.

Étape 10 - Water vapour

It is advisable to have a minimum of water when combustion happens, as it already produces a lot. In addition, condensation in pipes risks to block the lower parts of the gas circuit. To remove water vapour :

• Place a waste collector at the lowest point of the system.

• If the gas circuit is long, install collectors every 5 meters, at the lowest points of the circuit.

• A draining plug at the bottom the collectors allows for regular removal of water.

The bubbler reservoir can play this role of water collector if it placed at the lowest of the gas circuit.

Étape 11 - Hydrogen sulphide

Hydrogen sulphide (H₂S) is burnable but produces sulfuric acid, which is highly corrosive. A good pH balance in the biodigestor avoids most of hydrogen sulphide production. To eliminate it, biomethane will go through iron oxide, or iron straw, that will be regenerated by exposing it to the air (sulfur will leave). Coal or clay balls can also serve as filters for hydrogen sulphide.

Étape 12 - Gas circuit - Storage

In the digestor, it is advised that fermentation takes place at a minimum pressure. Gas will therefore has to be evacuate along its production. Unless gas consumption is continuous and regular, it is necessary to have a storage place, supplying gas only when necessary.

Flexible reservoirs, "bladder" like, are interesting. Using a non-flexible container can be dangerous: because we will need to empty it from air befor introducing methane. Mixing air and methane can be explosive.

• Assemble the storage reservoir simultaneously to the gas circuit.

• Place a 100mbar safety valve as close as possible to the storage. It will remove gas in case of potentially dangerous overpressure.

Étape 13 - Gas circuit - Flashback

In any place where a flashback is feared, place a ball of iron straw or copper straw on the gas circuit. Through thermic conduction, it will decreases temperature and stifle the combustion. Be careful however not to compact too much the metallic straw in the pipes, otherwise it would impede a good circulation of gas.

In our case, to avoid flashbacks to the digestor and above all to the storage reservoir, we place iron straw in the closest pipe to the gas cooker.

Étape 14 - Gas circuit - Combustion

Réglage des bruleurs

As it is mixed with non combustible carbon dioxyde, biomethane has a lower calorific power than propane, butane of pure methane for the same volume.

Therefore, devices functionning with these gases have a higher air admission than a gas cooker using biomethane.

To adapt standard burners to biomethane :

• Slightly close primary air arrival, with a metallic ring or with aluminium.

OR

• Disassemble the gas nozzle and use direct gas ejection.

CAUTION: flames from methane are less visible than from propane or butane, be careful not to get burned when using the gas cooker.

Autres utilisations

Biomethane can also be used in gas lamps, heaters, or combustion engines: generators, agricultural machines, cars...

Pression

The biodigestor and the storage are at atmospheric pressure, to ensure correct work of bacterias. The gas cooker will use 10mbar pressure. To provide this pressure:

• Install a compressor between the storage and the burner,

OR

• Press the flexible reservoir (10 cm of water). It will reduce methane production by 5% but is less expensive then buying a compressor.

Étape 16 - Digestor usage - Feed

The biodigestor is a living system, composed by billions of bacterias, and needs to be taken care of.

Alimentation régulière

Ideally, the biodigestor has to be fed every day. It is possible to reduce it until once a week at the minimum. If the volume of organic matter is too important, it is advised to divide it in different "meals".

It is important to shred or grind the organic matter (knive, blender...) and to add their weight in water, in order to :

• Prevent the matter from blocking the system,

• Accelerate degradation and system productivity.

Alimentation équilibrée

Biodigestor can be complementary to a compost. Indeed, compost creates humus, and needs a high carbon/nitrogen ratio (20 to 30), with mostly cellulose and lignous compounds. Too much putrescible organic matter will destructurate the compost.

Conversely, wet and putrescible matters are welcome in a biodigestor (fruits and vegetables, peelings ...) Fibrous, dry and hard matters need to be limited in the biodigestor. They may be the cause for blockage of the system, and remain in the digestor forming foam or a crust, that is difficult to remove.

High nitrogen input is ideal in the digestor, as it will stimulate bacterias activity. In addition, the digestate produced will be a rich fertilizer.

It is important to bring "green food" in the digestor diet. If peelings and leafstalks are not enough, it is possible to add grass.

Animal products (meat, milk, eggs...) should be avoided in the digestor, as it does not reaches high temperatures enough to detroy pathogens, unlike compost.

Oils have an important methanogen power (780 liters of methane per kilogram of oil!) but it brings acidity to the digestor, which might kill the bacterias when too important. Oils should be brought to the system sparingly.

Cooking water allows for system heating and fluidifies circulation. It also provides starch (potatoes, cereals, rice ...) that bacterias like.

Urine can be used in a regular basis. Feces are accepted sparingly, but they have a weak methanogen power, as an important part of their energetic value has already been absorbed during digestion.

pH

In acid medium, the enzymatic activity of the bacterias is inhibited. This acidity is mainly due to organic acids accumulation. In basic medium, fermentation produce hydrogen sulphide (H2S) and hydrogen (H2). Digestion can take place between pH of 6,6 and 7,6, with an optimum between 7 and 7,2.