Difference between revisions of "Hydroponie/en"

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{{ {{tntn|Tuto Details}}
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{{Tuto Details
 
|Main_Picture=Hydroponie_IMG_2667.JPG
 
|Main_Picture=Hydroponie_IMG_2667.JPG
 
|Licences=Attribution (CC BY)
 
|Licences=Attribution (CC BY)
|Description=<span class="mw-translate-fuzzy">This tutorial aims to introduce hydroponics and how to build an individual system. This technology was documented during a stopover in Singapore of the "Nomade des Mers" expedition. We met Comcrop, a company that grows aromatic plants (basil, mint...) on an area that is usually unused and worthless: the roofs of buildings!</span>
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|Description=This tutorial aims to introduce hydroponics and how to build an individual system. This technology was documented during a stopover in Singapore of the "Nomade des Mers" expedition. We met Comcrop, a company that grows aromatic plants (basil, mint...) on an area that is usually unused and worthless: the roofs of buildings!
 
|Area=Food
 
|Area=Food
 
|Type=Tutorial
 
|Type=Tutorial
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|Cost=50
 
|Cost=50
 
|Currency=EUR (€)
 
|Currency=EUR (€)
|Tags=Hydroponie, Agriculture urbaine, culture, Bioponie, plantes, légumes, NomadeDesMers, Nomade des Mers
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|Tags=Hydroponie, Agriculture urbaine, culture, Bioponie, plantes, légumes, NomadeDesMers, urine, organique, hydroponics, jardin intérieur, bioponics
 
|SourceLanguage=fr
 
|SourceLanguage=fr
 
|Language=en
 
|Language=en
 
|IsTranslation=1
 
|IsTranslation=1
 
}}
 
}}
{{ {{tntn|Introduction}}
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{{Introduction
 
|Introduction=Hydroponics is the cultivation of plants and vegetation above ground and in water. The roots are immersed in a neutral and inert substrate (such as clay balls, sand...) which serves as a support. They directly capture the nutrients necessary for their growth in water enriched with a nutrient solution. Unlike conventional hydroponics, bioponics (hydroponics+organic) allows fruits and vegetables to be grown organically without the use of synthetic chemical fertilizers. These are replaced by organic fertilizers such as manure, earthworm, urine or compost juice.
 
|Introduction=Hydroponics is the cultivation of plants and vegetation above ground and in water. The roots are immersed in a neutral and inert substrate (such as clay balls, sand...) which serves as a support. They directly capture the nutrients necessary for their growth in water enriched with a nutrient solution. Unlike conventional hydroponics, bioponics (hydroponics+organic) allows fruits and vegetables to be grown organically without the use of synthetic chemical fertilizers. These are replaced by organic fertilizers such as manure, earthworm, urine or compost juice.
  
In biopony, the nutrient solution is not sterile and bacteria, micro-organisms and fungi can develop. These active micro-organisms will make it possible to transform certain substances such as ammonia into nitrate, one of the nutrients essential for plant growth. In our case we use an organic solution by mixing water with human urine (1% urine in relation to the volume of water).  
+
In biopony, the nutrient solution is not sterile and bacteria, micro-organisms and fungi can develop. These active micro-organisms will make it possible to transform certain substances such as ammonia into nitrate, one of the nutrients essential for plant growth. In our case we use an organic solution by mixing water with human urine ('''1% urine in relation to the volume of water''').
 +
 
 +
"'Hydroponics has many advantages in certain contexts:"'
  
"Hydroponics has many advantages in certain contexts:
 
 
* In arid regions where fertile land and water are scarce. Hydroponics can save 7 to 10 times the volume of water needed for irrigation compared to conventional agriculture. It also helps to avoid water stress.  
 
* In arid regions where fertile land and water are scarce. Hydroponics can save 7 to 10 times the volume of water needed for irrigation compared to conventional agriculture. It also helps to avoid water stress.  
 
* In cities and urban areas where there is little space available for earth cultivation. It is particularly suitable for cultivation in restricted spaces (roofs of buildings, apartments, abandoned factories, etc.). As it can be developed vertically, hydroponics also makes it possible to obtain a production per square meter much higher than land agriculture. It can also allow a return to culture among urban residents, who are often disconnected from nature.
 
* In cities and urban areas where there is little space available for earth cultivation. It is particularly suitable for cultivation in restricted spaces (roofs of buildings, apartments, abandoned factories, etc.). As it can be developed vertically, hydroponics also makes it possible to obtain a production per square meter much higher than land agriculture. It can also allow a return to culture among urban residents, who are often disconnected from nature.
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* Allows better control of invasive insects.
 
* Allows better control of invasive insects.
  
*Dans les régions arides où les terres fertiles et l'eau se font rares. '''L'hydroponie permet de faire économiser de 7 à 10 fois les volumes d'eau''' nécessaires à l'irrigation en comparaison avec l'agriculture conventionnelle. Elle permet également d'éviter les stress hydriques.
+
"'But hydroponics can also have disadvantages:"'
*Dans les villes et zones urbaines où peu d'espaces sont disponibles à la culture en terre. Elle convient particulièrement à la '''culture dans des espaces restreints''' (toits d'immeubles, appartements, usine désaffectée...). Pouvant être développée de manière verticale, l'hydroponie permet également d'obtenir '''une production au mètre carré bien supérieure''' à l'agriculture en terre. Elle peut également permettre un retour à la culture chez les citadins, souvent déconnectés de la nature.
 
*En cas de '''pollution des sols.'''
 
*Permet de mieux contrôler les insectes invasifs.
 
  
"But hydroponics can also have disadvantages:
 
 
* Can be expensive and uneconomical if installed in greenhouses with artificial lighting and heating.
 
* Can be expensive and uneconomical if installed in greenhouses with artificial lighting and heating.
 
* In a non-organic hydroponic system, the nutrient solution must be renewed regularly.  Water rich in minerals and oligo-elements is then rejected and can affect the ecosystem. In this tutorial, we present a method to avoid chemical inputs.  
 
* In a non-organic hydroponic system, the nutrient solution must be renewed regularly.  Water rich in minerals and oligo-elements is then rejected and can affect the ecosystem. In this tutorial, we present a method to avoid chemical inputs.  
 
* The environment being humid and hot, bacteria or diseases can spread very quickly. Hydroponics requires particular and daily attention to the health of plants.
 
* The environment being humid and hot, bacteria or diseases can spread very quickly. Hydroponics requires particular and daily attention to the health of plants.
 
*Peut s'avérer coûteuse et peu écologique si elle est mise en place sous serre avec éclairage artificiel et chauffage.
 
*Dans un système d'hydroponie non biologique, la solution nutritive doit être renouvelée régulièrement.  De l'eau riche en minéraux et oligo-éléments est alors rejetée et peut affecter l'écosystème. Dans ce tutoriel, nous présentons une méthode permettant d'éviter les intrants chimiques.
 
*Le milieu étant humide et chaud, les bactéries ou maladies peuvent se propager très rapidement. L'hydroponie demande une attention particulière et quotidienne à la bonne santé des plantes.
 
 
}}
 
}}
{{ {{tntn|TutoVideo}}
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{{TutoVideo
 
|VideoType=Youtube
 
|VideoType=Youtube
 
|VideoURLYoutube=https://youtu.be/T_qywsqM2UA
 
|VideoURLYoutube=https://youtu.be/T_qywsqM2UA
 
}}
 
}}
{{ {{tntn|Materials}}
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{{Materials
|Material=<div class="mw-translate-fuzzy">
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|Material=1. Crop gutters
1. Crop gutters
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((* Cleats (minimum width 10cm))
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* Cleats (minimum width 10cm)
 
* Plastic sheeting
 
* Plastic sheeting
 
* Staples
 
* Staples
 
* Clay beads
 
* Clay beads
{{Prefer the small clay balls, they are heavier and will allow a better maintenance of the roots
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{{Info|Prefer the small clay balls, they are heavier and will allow a better maintenance of the roots
 
}}
 
}}
 +
 
* Brackets
 
* Brackets
 
* Wood screws
 
* Wood screws
 
* Young shoots and cuttings
 
* Young shoots and cuttings
 +
 
2. Irrigation system
 
2. Irrigation system
 +
 
* 1 Submersible pump (aquarium pump)
 
* 1 Submersible pump (aquarium pump)
 
* 5 m of thin plastic pipe (pump outlet)
 
* 5 m of thin plastic pipe (pump outlet)
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* 1 Wide pipe end cap (to be fixed on the filter tank)
 
* 1 Wide pipe end cap (to be fixed on the filter tank)
 
* 1 Blower
 
* 1 Blower
 +
 
3. Filter and bio-filter
 
3. Filter and bio-filter
 +
 
* 2 plastic bins of 60L  
 
* 2 plastic bins of 60L  
 
* Large gravel  
 
* Large gravel  
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{{In order to ensure homogeneity of the water in terms of nutrients and temperature, we recommend using about 40L of water per square meter of cultivation. }}
 
{{In order to ensure homogeneity of the water in terms of nutrients and temperature, we recommend using about 40L of water per square meter of cultivation. }}
 
4. Control system
 
4. Control system
 +
 
* Socket outlet with programmable timer or Arduino
 
* Socket outlet with programmable timer or Arduino
</div>
 
 
*Tasseaux (10cm de largeur minimum)
 
*Bâche plastique
 
*Agrafes
 
*Billes d'argiles
 
{{Info|Préférer les petites billes d'argiles, celles-ci sont plus lourdes et permettront un meilleur maintien des racines
 
}}
 
 
*Équerres
 
*Vis à bois
 
*Jeunes pousses et boutures
 
 
2. Système d'irrigation
 
 
*1 Pompe immergée (pompe d'aquarium)
 
*5 m de tuyau plastique fin (Sortie pompe)
 
*1 Embout avec 4 sorties pour tuyau fin
 
*50 cm de tuyau plastique large (Lien entre le filtre et le bio-filtre)
 
*1 Embout de tuyau large (à fixer sur le bac du filtre)
 
*1 Bulleur
 
 
3. Filtre et bio-filtre
 
 
*2 Bacs en plastique de 60L
 
*Gros gravier
 
*Sable
 
*10L Billes d'argile
 
*40L d'eau
 
{{Info|Afin d'assurer une homogénéité de l'eau en nutriments et en température, nous conseillons d'utiliser environ 40L d'eau par mètre carré de culture. }}
 
4. Système de commande
 
 
*Prise de courant avec minuterie programmable ou Arduino
 
 
|Tools=* Drill/driver or screwdriver
 
|Tools=* Drill/driver or screwdriver
 
* Saw
 
* Saw
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* Hole saw
 
* Hole saw
 
* Cutter or scissors
 
* Cutter or scissors
 +
|Tuto_Attachments={{Tuto Attachments
 +
|Attachment=Hydroponie_11_ForumClimat_HydroponieActive_VF_1_.pdf
 +
}}
 
}}
 
}}
{{ {{tntn|Tuto Step}}
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{{Tuto Step
 
|Step_Title=Manufacture of culture gutters
 
|Step_Title=Manufacture of culture gutters
|Step_Content=The system used measures 2m long by 50cm wide. The skeleton is made up of 4 cleats / bamboos fixed in parallel at a distance of 15 cm thanks to wooden cleats. It is covered with an agricultural cover (width 1m) so as to form 3 gutters about 10cm deep. These gutters are filled with clay balls. An aquarium pump immersed in the biofilter tank propels the nutrient solution from the top side of these gutters (inclination of about 10 degrees) so that it flows through the clay balls until it returns to the storage tank (biofilter). The table is about 1.2m high (ergonomic for taking care of plants). A shade screen is attached like a skirt on the sides to protect the biofilters, nutrient solution storage tank and mushroom farm from the sun.  
+
|Step_Content=The system used measures 2m long by 50cm wide. The skeleton is made up of 4 cleats / bamboos fixed in parallel at a distance of 15 cm thanks to wooden cleats. It is covered with an agricultural cover (width 1m) so as to form 3 gutters about 10cm deep. These gutters are filled with clay balls. An aquarium pump immersed in the biofilter tank propels the nutrient solution from the top side of these gutters (inclination of about 10 degrees) so that it flows through the clay balls until it returns to the storage tank (biofilter). The table is about 1.2m high (ergonomic for taking care of plants). A shade screen is attached like a skirt on the sides to protect the biofilters, nutrient solution storage tank and mushroom farm from the sun.
 +
 
 
# Manufacturing of the support
 
# Manufacturing of the support
 +
 
* In this model we explain the process for 3 gutters but it is of course possible to duplicate it at will !
 
* In this model we explain the process for 3 gutters but it is of course possible to duplicate it at will !
 
* Cut 4 strips of the same length (190 cm for us)
 
* Cut 4 strips of the same length (190 cm for us)
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* Form gutters with the tarpaulin until it touches the support
 
* Form gutters with the tarpaulin until it touches the support
 
* Staple the tarpaulin on each strip and cut it out.
 
* Staple the tarpaulin on each strip and cut it out.
* Water recovery  
+
* Water recovery
 
 
#Fabrication du support
 
 
 
*Dans ce modèle nous expliquons le procédé pour 3 gouttières mais il est bien-sûr possible de le dupliquer à volonté !
 
*Découper 4 tasseaux de mêmes longueurs (190 cm pour nous)
 
*Les fixer parallèlement sur un support grâce aux équerres et aux vis à intervalle régulier (15 cm)
 
*Agrafer la bâche sur le côté du premier tasseau puis l'étendre pour recouvrir les 3 suivants (Possibilité de doubler la bâche pour plus de résistance)
 
*Former des gouttières avec la bâche jusqu'à ce qu'elle touche le support
 
*Agrafer la bâche sur chaque tasseau puis découper là.
 
*Récupération de l'eau
 
  
 
2. Water recovery
 
2. Water recovery
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|Step_Picture_04=Hydroponie_IMG_2678.JPG
 
|Step_Picture_04=Hydroponie_IMG_2678.JPG
 
}}
 
}}
{{ {{tntn|Tuto Step}}
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{{Tuto Step
 
|Step_Title=Filter and Biofilter
 
|Step_Title=Filter and Biofilter
 
|Step_Content=Once passed through the plants, the water flows into two separate tanks: the filter and the biofilter.
 
|Step_Content=Once passed through the plants, the water flows into two separate tanks: the filter and the biofilter.
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- The purpose of the filter is to block all coarse particles that could block the pumps (root and leaf residues, erosion of clay balls, etc.). The filter has three stages of filtration, from the finest to the coarsest.
 
- The purpose of the filter is to block all coarse particles that could block the pumps (root and leaf residues, erosion of clay balls, etc.). The filter has three stages of filtration, from the finest to the coarsest.
  
- The biofilter constitutes the water reservoir, to which is added about a quarter of the volume in clay beads. These serve as a culture medium for bacteria that will allow the transformation of natural inputs (urine, compost juice, etc.) into nutrients that can be assimilated by plants. In particular, the transformation of ammonia into nitrite and then nitrate, essential for foliar development (leaf development). Bacteria develop naturally after 6 weeks or can be purchased in culture at hydroponics sites.  
+
- The biofilter constitutes the water reservoir, to which is added about a quarter of the volume in clay beads. These serve as a culture medium for bacteria that will allow the transformation of natural inputs (urine, compost juice, etc.) into nutrients that can be assimilated by plants. In particular, the transformation of ammonia into nitrite and then nitrate, essential for foliar development (leaf development). Bacteria develop naturally after 6 weeks or can be purchased in culture at hydroponics sites.
 +
 
 +
For their proper development, bacteria need:
  
For their proper development, bacteria need:
 
 
* of moisture, provided by water  
 
* of moisture, provided by water  
 
* shadow  
 
* shadow  
 
* of oxygen, install a bubbler to regularly stir the water in the biofilter.  
 
* of oxygen, install a bubbler to regularly stir the water in the biofilter.  
* of food, natural inputs  
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* of food, natural inputs
For our part, we only use human urine as an input (See below for assays)!
 
  
*d'humidité, apportée par l'eau
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<div class="mw-translate-fuzzy">
*d'ombre
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For our part, we only use human urine as an input (1mL/1L of water)
*d’oxygène, installer un bulleur afin de remuer régulièrement l'eau du biofiltre.
+
</div>
*de nourriture, les intrants naturels
 
  
Pour notre part, nous utilisons uniquement de l'urine humaine comme intrant (Voir plus bas pour les dosages) !
+
{{Info|If you use chemical inputs (not so good...) you won't need a biofilter.}}
  
{{Info|If you use chemical inputs (not so good...) you won't need a biofilter.}}
 
 
# Filter
 
# Filter
 +
 
* At the bottom of the first tank, drill a hole with the hole saw of the diameter of your outlet pipe to the second tank.
 
* At the bottom of the first tank, drill a hole with the hole saw of the diameter of your outlet pipe to the second tank.
 
* Install the nozzle and hose on the tank
 
* Install the nozzle and hose on the tank
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* Install the filter under the water pocket at the outlet of the gutter, and raise it above the biofilter to allow the water to flow by gravity.
 
* Install the filter under the water pocket at the outlet of the gutter, and raise it above the biofilter to allow the water to flow by gravity.
  
#Filtre
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2. Biofilter
  
*En bas du premier bac, percer un trou avec la scie cloche du diamètre de votre tuyau de sortie vers le deuxième bac.
 
*Installer l'embout et le tuyau sur le bac
 
*Étaler une couche de gravier assez gros au fond (1/4 du volume du filtre)
 
*Ajouter une couche de billes d'argile de la même épaisseur
 
*Ajouter une couche de sable un peu plus fine au dessus
 
*Installer le filtre sous la poche d'eau en sortie de la gouttière, et le surélever par rapport au biofiltre pour permettre à l'eau de s'écouler par gravité.
 
 
2. Biofilter
 
 
* Fill the second tank with water (40L) and add about a quarter of the volume of water in clay balls (10L)
 
* Fill the second tank with water (40L) and add about a quarter of the volume of water in clay balls (10L)
  
*Remplir le second bac d'eau (40L) et ajouter environ un quart du volume d'eau en billes d'argiles (10L)
+
<div class="mw-translate-fuzzy">
 
+
{{Info|In our system, the clay beads of the biofilter are replaced by plastic beads that are also good nests for bacteria (but not natural).}}
In our system, the clay beads of the biofilter are replaced by plastic beads that are also good nests for bacteria (but not natural).
+
</div>
 
|Step_Picture_00=Hydroponie_IMG_2663.JPG
 
|Step_Picture_00=Hydroponie_IMG_2663.JPG
 
|Step_Picture_01=Hydroponie_IMG_2701.JPG
 
|Step_Picture_01=Hydroponie_IMG_2701.JPG
 
|Step_Picture_02=Culture_en_hydroponie_IMG-20190216-WA0000.jpg
 
|Step_Picture_02=Culture_en_hydroponie_IMG-20190216-WA0000.jpg
 +
|Step_Picture_03=Hydroponie_Dessin_hydroponie2.jpg
 
}}
 
}}
{{ {{tntn|Tuto Step}}
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{{Tuto Step
 
|Step_Title=Irrigation system and bubbler
 
|Step_Title=Irrigation system and bubbler
|Step_Content=After being filtered, oxygenated and recharged with nutrients, the water is ready to be re-injected into the system. For this purpose, a small submersible pump is used. The power of the pump depends on the size of your system.  
+
|Step_Content=After being filtered, oxygenated and recharged with nutrients, the water is ready to be re-injected into the system. For this purpose, a small submersible pump is used. The power of the pump depends on the size of your system.
 +
 
 
*Measure a length of plastic pipe (of a diameter suitable for your pump) from the biofilter to the end of the gutters.
 
*Measure a length of plastic pipe (of a diameter suitable for your pump) from the biofilter to the end of the gutters.
 
*Connect one end to the pump and the other to a 4-way nozzle (to be adapted according to the number of gutters), placed at the end of the gutters
 
*Connect one end to the pump and the other to a 4-way nozzle (to be adapted according to the number of gutters), placed at the end of the gutters
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*Connect pipes to the outlets of the nozzle to irrigate all gutters.
 
*Connect pipes to the outlets of the nozzle to irrigate all gutters.
 
*Immerse the pump in the biofilter
 
*Immerse the pump in the biofilter
*Immerse the bubbler in the biofilter  
+
*Immerse the bubbler in the biofilter
 
 
*Mesurer une longueur de tuyau en plastique (d'un diamètre adapté à votre pompe) allant du biofiltre à l'extrémité des gouttières.
 
*Connecter une extrémité à la pompe et l'autre, à un embout à 4 sorties (à adapter en fonction du nombre de gouttières), placé à l’extrémité des gouttières
 
*Fixer cet embout au niveau de la gouttière centrale.
 
*Connecter des tuyaux aux sorties de l'embout afin d'irriguer toutes les gouttières.
 
*Plonger la pompe dans le biofiltre
 
*Plonger le bulleur dans le biofiltre
 
 
|Step_Picture_00=Culture_en_hydroponie_IMG_20190216_091357.jpg
 
|Step_Picture_00=Culture_en_hydroponie_IMG_20190216_091357.jpg
 
|Step_Picture_01=Hydroponie_IMG_2703.JPG
 
|Step_Picture_01=Hydroponie_IMG_2703.JPG
 
}}
 
}}
{{ {{tntn|Tuto Step}}
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{{Tuto Step
 
|Step_Title=Control system
 
|Step_Title=Control system
 
|Step_Content=In order to gain in autonomy, it is possible to install a timer system thanks to a programmable electrical socket or an arduino allowing to program the starting of the pump and the bubbler.
 
|Step_Content=In order to gain in autonomy, it is possible to install a timer system thanks to a programmable electrical socket or an arduino allowing to program the starting of the pump and the bubbler.
 +
 
* Indeed, for a better development of the plants, it is advisable to proceed to a regular watering alternated with dry breaks. This water stress will strengthen the roots.
 
* Indeed, for a better development of the plants, it is advisable to proceed to a regular watering alternated with dry breaks. This water stress will strengthen the roots.
 +
 
For this purpose, we recommend that the pump be switched on for 30 minutes every 2 hours during the day. No watering at night.
 
For this purpose, we recommend that the pump be switched on for 30 minutes every 2 hours during the day. No watering at night.
 +
 
* The biofilter needs to be aerated regularly for good growth and survival of bacteria.
 
* The biofilter needs to be aerated regularly for good growth and survival of bacteria.
"We recommend lighting the bubbler for 1 minute every 5 minutes, 24 hours a day.
 
 
*En effet, pour un meilleur développement des plantes, il est conseillé de procéder à un arrosage régulier alterné avec des temps de pauses sèches. Ce stress hydrique permettra un renforcement des racines.
 
  
'''Pour cela, nous conseillons un allumage de la pompe pendant 30 min toutes les 2h, durant la journée. Pas d'arrosage la nuit.'''
+
'''We recommend lighting the bubbler for 1 minute every 5 minutes, 24 hours a day.'''
  
*Le biofiltre a besoin d'être aéré régulièrement pour une bonne croissance et la survie des bactéries.
+
'''Arduino control system: '''
 
 
'''Nous conseillons un allumage du bulleur 1 minute toutes les 5 minutes, 24h/24.'''
 
 
 
Arduino control system: http://lowtechlab.org/wiki/Gestion_%C3%A9nerg%C3%A9tique_d%27un_syst%C3%A8me_d%27hydroponie/fr
 
  
 
[[Gestion énergétique d'un système d'hydroponie/fr]]
 
[[Gestion énergétique d'un système d'hydroponie/fr]]
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<br />
 
<br />
 
}}
 
}}
{{ {{tntn|Tuto Step}}
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{{Tuto Step
 
|Step_Title=Crop selection and harvesting
 
|Step_Title=Crop selection and harvesting
 
|Step_Content=Not all crops are suitable for hydroponics. It is easier, especially without chemical fertilizers, to prefer leafy vegetables (lettuce, cabbage, spinach, sweet potatoes...) and herbs (mint, basil, coriander).
 
|Step_Content=Not all crops are suitable for hydroponics. It is easier, especially without chemical fertilizers, to prefer leafy vegetables (lettuce, cabbage, spinach, sweet potatoes...) and herbs (mint, basil, coriander).
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"It is always necessary to integrate the plants after sowing or cutting them so that they have developed a long and strong root system. "
 
"It is always necessary to integrate the plants after sowing or cutting them so that they have developed a long and strong root system. "
  
<div class="mw-translate-fuzzy">
 
 
Some advice:
 
Some advice:
 +
 
* Prefer direct light if possible but do not hesitate to add shade in case of high heat.
 
* Prefer direct light if possible but do not hesitate to add shade in case of high heat.
 
* Ventilate the system well and control the temperature. Do not hesitate to add a small fan in case of high heat.  
 
* Ventilate the system well and control the temperature. Do not hesitate to add a small fan in case of high heat.  
 
* Regularly check that the roots are under the clay balls.
 
* Regularly check that the roots are under the clay balls.
 
* Check the colour of the leaves regularly: if they turn yellow, this may be due to excessive watering, lack of nutrients, poor pH or too much sunlight.
 
* Check the colour of the leaves regularly: if they turn yellow, this may be due to excessive watering, lack of nutrients, poor pH or too much sunlight.
</div>
 
 
*Préférer la lumière directe si possible mais ne pas hésiter à ajouter de l'ombrage en cas de grosses chaleurs
 
*Bien aérer le système et contrôler la température. Ne pas hésiter à ajouter un petit ventilateur en cas de grosses chaleurs.
 
*Vérifier régulièrement que les racines soient sous les billes d'argiles.
 
*Vérifier régulièrement la couleur des feuilles: si celles-ci jaunissent, cela peut être dû à un arrosage excessif, un manque de nutriments, un mauvais pH ou un trop fort ensoleillement.
 
  
<div class="mw-translate-fuzzy">
 
 
* Transplant the shoots at the end of the day.  
 
* Transplant the shoots at the end of the day.  
 
* Transplant the shoots when they have at least 5 leaves. Then you have to water.
 
* Transplant the shoots when they have at least 5 leaves. Then you have to water.
 
* Cuttings: for mint and sweet potatoes, for example, cut one or more branches. Remove the leaves on about 2/3 of the branch. Bury this cleared area under the clay balls. Then you have to water.
 
* Cuttings: for mint and sweet potatoes, for example, cut one or more branches. Remove the leaves on about 2/3 of the branch. Bury this cleared area under the clay balls. Then you have to water.
 
* Harvest in the morning, shortly after sunrise. Choose the oldest, most damaged leaves or leaves that develop in parallel with auxiliary shoots.
 
* Harvest in the morning, shortly after sunrise. Choose the oldest, most damaged leaves or leaves that develop in parallel with auxiliary shoots.
</div>
 
 
|Step_Picture_00=Hydroponie_IMG_2648.JPG
 
|Step_Picture_00=Hydroponie_IMG_2648.JPG
 
}}
 
}}
{{ {{tntn|Notes}}
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|Step_Content=Vous pouvez télécharger une fiche pédagogique créée par le Low-tech Lab à l'occasion de l'exposition "En Quête d'un Habitat Durable" dans la partie "Fichiers" du tutoriel (onglet au niveau de la section "Outils-Matériaux")
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====Utilisation de l'urine comme fertilisant====
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1L of urine contains on average 6g of nitrogen, 1g of phosphorus (directly assimilable) and 2g of potassium. Nitrogen is in the form of urea, which will be transformed into ammonia on contact with the air. It is this step that produces the odor associated with urine, but it is eliminated by the action of micro-organisms or by storage without contact with air.
 +
 
 +
Plants are able to assimilate nitrogen in two forms: ammonium NH4+ and nitrate NO3-, with a preference given to nitrate in most cases. The biofilter enables this transformation.
 +
 
 +
Il est important de diluer l'azote pour éviter une concentration trop forte en sels.
 +
===Références===
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*FAO's detailed report on small-scale aquaponics: http://www.fao.org/3/a-i4021e.pdf
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*Antroponics: specialized website on the experimentation of human urine in hydroponics: http://anthroponics.com/
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*Arduino control system: [[Gestion énergétique d'un système d'hydroponie/fr]]
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*Tutorial written by Guénolé Conrad, Valentin Coyard and Coline Billon in January 2020
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*English translation: Guénolé Conrad
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*Spanish translation: Viridiana Arenas
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Latest revision as of 12:16, 26 March 2021

Tutorial de avatarLow-tech Lab | Categories : Food

Hydroponie IMG 2667.JPG

This tutorial aims to introduce hydroponics and how to build an individual system. This technology was documented during a stopover in Singapore of the "Nomade des Mers" expedition. We met Comcrop, a company that grows aromatic plants (basil, mint...) on an area that is usually unused and worthless: the roofs of buildings!

License : Attribution (CC BY)

Introduction

Hydroponics is the cultivation of plants and vegetation above ground and in water. The roots are immersed in a neutral and inert substrate (such as clay balls, sand...) which serves as a support. They directly capture the nutrients necessary for their growth in water enriched with a nutrient solution. Unlike conventional hydroponics, bioponics (hydroponics+organic) allows fruits and vegetables to be grown organically without the use of synthetic chemical fertilizers. These are replaced by organic fertilizers such as manure, earthworm, urine or compost juice.

In biopony, the nutrient solution is not sterile and bacteria, micro-organisms and fungi can develop. These active micro-organisms will make it possible to transform certain substances such as ammonia into nitrate, one of the nutrients essential for plant growth. In our case we use an organic solution by mixing water with human urine (1% urine in relation to the volume of water).

"'Hydroponics has many advantages in certain contexts:"'

  • In arid regions where fertile land and water are scarce. Hydroponics can save 7 to 10 times the volume of water needed for irrigation compared to conventional agriculture. It also helps to avoid water stress.
  • In cities and urban areas where there is little space available for earth cultivation. It is particularly suitable for cultivation in restricted spaces (roofs of buildings, apartments, abandoned factories, etc.). As it can be developed vertically, hydroponics also makes it possible to obtain a production per square meter much higher than land agriculture. It can also allow a return to culture among urban residents, who are often disconnected from nature.
  • In case of soil pollution.
  • Allows better control of invasive insects.

"'But hydroponics can also have disadvantages:"'

  • Can be expensive and uneconomical if installed in greenhouses with artificial lighting and heating.
  • In a non-organic hydroponic system, the nutrient solution must be renewed regularly. Water rich in minerals and oligo-elements is then rejected and can affect the ecosystem. In this tutorial, we present a method to avoid chemical inputs.
  • The environment being humid and hot, bacteria or diseases can spread very quickly. Hydroponics requires particular and daily attention to the health of plants.

Video overview

Materials

1. Crop gutters

  • Cleats (minimum width 10cm)
  • Plastic sheeting
  • Staples
  • Clay beads
Prefer the small clay balls, they are heavier and will allow a better maintenance of the roots
  • Brackets
  • Wood screws
  • Young shoots and cuttings

2. Irrigation system

  • 1 Submersible pump (aquarium pump)
  • 5 m of thin plastic pipe (pump outlet)
  • 1 End cap with 4 outlets for fine pipe
  • 50 cm of wide plastic tube (Link between the filter and the bio-filter)
  • 1 Wide pipe end cap (to be fixed on the filter tank)
  • 1 Blower

3. Filter and bio-filter

  • 2 plastic bins of 60L
  • Large gravel
  • Sand
  • 10L Clay beads
  • 40L of water

Modèle:In order to ensure homogeneity of the water in terms of nutrients and temperature, we recommend using about 40L of water per square meter of cultivation. 4. Control system

  • Socket outlet with programmable timer or Arduino

Tools

  • Drill/driver or screwdriver
  • Saw
  • Stapler
  • Hole saw
  • Cutter or scissors

Step 1 - Manufacture of culture gutters

The system used measures 2m long by 50cm wide. The skeleton is made up of 4 cleats / bamboos fixed in parallel at a distance of 15 cm thanks to wooden cleats. It is covered with an agricultural cover (width 1m) so as to form 3 gutters about 10cm deep. These gutters are filled with clay balls. An aquarium pump immersed in the biofilter tank propels the nutrient solution from the top side of these gutters (inclination of about 10 degrees) so that it flows through the clay balls until it returns to the storage tank (biofilter). The table is about 1.2m high (ergonomic for taking care of plants). A shade screen is attached like a skirt on the sides to protect the biofilters, nutrient solution storage tank and mushroom farm from the sun.

  1. Manufacturing of the support
  • In this model we explain the process for 3 gutters but it is of course possible to duplicate it at will !
  • Cut 4 strips of the same length (190 cm for us)
  • Attach them parallel to a support using brackets and screws at regular intervals (15 cm)
  • Staple the tarpaulin on the side of the first strip and then extend it to cover the next three (Possibility to double the tarpaulin for more resistance)
  • Form gutters with the tarpaulin until it touches the support
  • Staple the tarpaulin on each strip and cut it out.
  • Water recovery

2. Water recovery

The water system operates in a closed circuit. The water is pumped into the biofilter that serves as a reservoir, exits at one end of the gutter and is recollected at the other end before passing through a filter and returning to the initial reservoir.

In order to recover the water, the tarpaulin is pierced very finely (to prevent the clay balls from escaping) at the opposite end of the water inlet. Below this end, another tarpaulin is stapled to form a pocket to collect and channel the water before it flows into the filter.

Step 2 - Filter and Biofilter

Once passed through the plants, the water flows into two separate tanks: the filter and the biofilter.

- The purpose of the filter is to block all coarse particles that could block the pumps (root and leaf residues, erosion of clay balls, etc.). The filter has three stages of filtration, from the finest to the coarsest.

- The biofilter constitutes the water reservoir, to which is added about a quarter of the volume in clay beads. These serve as a culture medium for bacteria that will allow the transformation of natural inputs (urine, compost juice, etc.) into nutrients that can be assimilated by plants. In particular, the transformation of ammonia into nitrite and then nitrate, essential for foliar development (leaf development). Bacteria develop naturally after 6 weeks or can be purchased in culture at hydroponics sites.

For their proper development, bacteria need:

  • of moisture, provided by water
  • shadow
  • of oxygen, install a bubbler to regularly stir the water in the biofilter.
  • of food, natural inputs

For our part, we only use human urine as an input (1mL/1L of water)

If you use chemical inputs (not so good...) you won't need a biofilter.
  1. Filter
  • At the bottom of the first tank, drill a hole with the hole saw of the diameter of your outlet pipe to the second tank.
  • Install the nozzle and hose on the tank
  • Spread a layer of coarse gravel on the bottom (1/4 of the filter volume)
  • Add a layer of clay beads of the same thickness
  • Add a slightly thinner layer of sand on top
  • Install the filter under the water pocket at the outlet of the gutter, and raise it above the biofilter to allow the water to flow by gravity.

2. Biofilter

  • Fill the second tank with water (40L) and add about a quarter of the volume of water in clay balls (10L)
In our system, the clay beads of the biofilter are replaced by plastic beads that are also good nests for bacteria (but not natural).


Step 3 - Irrigation system and bubbler

After being filtered, oxygenated and recharged with nutrients, the water is ready to be re-injected into the system. For this purpose, a small submersible pump is used. The power of the pump depends on the size of your system.

  • Measure a length of plastic pipe (of a diameter suitable for your pump) from the biofilter to the end of the gutters.
  • Connect one end to the pump and the other to a 4-way nozzle (to be adapted according to the number of gutters), placed at the end of the gutters
  • Attach this end cap to the central gutter.
  • Connect pipes to the outlets of the nozzle to irrigate all gutters.
  • Immerse the pump in the biofilter
  • Immerse the bubbler in the biofilter



Step 4 - Control system

In order to gain in autonomy, it is possible to install a timer system thanks to a programmable electrical socket or an arduino allowing to program the starting of the pump and the bubbler.

  • Indeed, for a better development of the plants, it is advisable to proceed to a regular watering alternated with dry breaks. This water stress will strengthen the roots.

For this purpose, we recommend that the pump be switched on for 30 minutes every 2 hours during the day. No watering at night.

  • The biofilter needs to be aerated regularly for good growth and survival of bacteria.

We recommend lighting the bubbler for 1 minute every 5 minutes, 24 hours a day.

Arduino control system:

Gestion énergétique d'un système d'hydroponie/fr


Step 5 - Crop selection and harvesting

Not all crops are suitable for hydroponics. It is easier, especially without chemical fertilizers, to prefer leafy vegetables (lettuce, cabbage, spinach, sweet potatoes...) and herbs (mint, basil, coriander).

"Plant" them in the clay balls, making sure that the roots are well immersed.

"It is always necessary to integrate the plants after sowing or cutting them so that they have developed a long and strong root system. "

Some advice:

  • Prefer direct light if possible but do not hesitate to add shade in case of high heat.
  • Ventilate the system well and control the temperature. Do not hesitate to add a small fan in case of high heat.
  • Regularly check that the roots are under the clay balls.
  • Check the colour of the leaves regularly: if they turn yellow, this may be due to excessive watering, lack of nutrients, poor pH or too much sunlight.
  • Transplant the shoots at the end of the day.
  • Transplant the shoots when they have at least 5 leaves. Then you have to water.
  • Cuttings: for mint and sweet potatoes, for example, cut one or more branches. Remove the leaves on about 2/3 of the branch. Bury this cleared area under the clay balls. Then you have to water.
  • Harvest in the morning, shortly after sunrise. Choose the oldest, most damaged leaves or leaves that develop in parallel with auxiliary shoots.




Step 6 - Contenu pédagogique à télécharger

Vous pouvez télécharger une fiche pédagogique créée par le Low-tech Lab à l'occasion de l'exposition "En Quête d'un Habitat Durable" dans la partie "Fichiers" du tutoriel (onglet au niveau de la section "Outils-Matériaux")




Notes and references

This section gathers the most frequently asked questions about this tutorial and the progress of the Low-tech Lab's thinking on these topics.

Utilisation de l'urine comme fertilisant

1L of urine contains on average 6g of nitrogen, 1g of phosphorus (directly assimilable) and 2g of potassium. Nitrogen is in the form of urea, which will be transformed into ammonia on contact with the air. It is this step that produces the odor associated with urine, but it is eliminated by the action of micro-organisms or by storage without contact with air.

Plants are able to assimilate nitrogen in two forms: ammonium NH4+ and nitrate NO3-, with a preference given to nitrate in most cases. The biofilter enables this transformation.

Il est important de diluer l'azote pour éviter une concentration trop forte en sels.

Références

  • Tutorial written by Guénolé Conrad, Valentin Coyard and Coline Billon in January 2020
  • English translation: Guénolé Conrad
  • Spanish translation: Viridiana Arenas


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