SUPPORTS FOR GROWING AN ORGANISM, USES OF SAID SUPPORTS AND GROWING AND PURIFICATION METHODS USING THESE SUPPORTS

Abstract

Porous support for growing an organism, comprising two walls capable of holding water, the two walls being designed to form at least one pocket for holding the organism, characterized in that each wall comprises at least one porous layer comprising a chemically inert and porous material allowing water to flow under the effect of gravity through the pores of the layer, the said layer being designed to allow the organism to cling on to it.

Claims

1. Porous support for growing an organism, comprising two walls capable of receiving water, the two walls being designed to form at least one pocket for receiving the organism wherein each wall comprises at least one porous layer comprising a chemically inert and porous material allowing water to flow under the effect of gravity through the pores of the layer, the said layer being designed to allow the organism to cling on to it.

2. Porous support according to claim 1, wherein the porous layer further comprises biodegradable fibres.

3. Porous support according to claim 2, wherein the porous layer comprises 2 to 10% in mass of the biodegradable fibres.

4. Porous support according to claim 2, wherein the biodegradable fibres come from one of the plants of the plant group comprising hemp and coco.

5. Porous support according to claim 1, wherein the porous layer allowing the organism to cling on to it, is an internal layer and each wall further comprises an external protective layer.

6. Porous support according to claim 5, wherein a dividing, porous and inert layer is provided in each wall.

7. Porous support to grow an organism with one single wall substantially horizontal, which can hold water, comprising a chemically inert and porous material allow water to flow under the effect of gravity through the pores of the layer, the said porous layer being designed to allow the organism to cling on to it.

8. Porous support according to claim 2, wherein the porous layer further comprises biodegradable fibres.

9. Porous support according to claim 1, wherein the inert and porous material comprises a polyolefin, preferably polypropylene.

10. Use of the porous support according to claim 1 to grow plants fertilised by organic fertilisers.

11. Use of the porous support according to claim 1 to grow cells chosen among aerobic bacteria, aerobic fungi and mixtures of these.

12. Method for growing aerobic bacteria and/or aerobic fungi comprising: the preparation of a porous support according to claim 1, the seeding of the said bacteria and/or the said fungi and the adding of a growing environment comprising water and organic nutrients.

13. Method according to claim 12, wherein the organic nutrients mainly come from waste.

14. Method for purifying a composition comprising organic compounds that come from biological waste comprising: the preparation of a porous support according to claim 1, the seeding of the said porous support with aerobic bacteria and/or aerobic fungi and/or plants and the adding the said composition to be purified to the said seeded support.

Description

[0022] The invention will be best understood upon reading the following description, in reference to the appended drawings, whereon

[0023] FIG. 1 represents a cross-section view of the two-walled growing support of the invention;

[0024] FIG. 2 schematically represents a view of the support face in FIG. 1 and

[0025] FIG. 3 represents a cross-section view of the single-walled growing support of the invention.

DETAILED DESCRIPTION OF THE INVENTION

[0026] In reference to FIG. 1, the support 5 for growing an organism 11, here a plant provided with leaves and flowers, comprises two walls 4, 4 facing each other, each wall comprising an internal, porous layer 1 comprising chemically inert fibres and here a few biodegradable fibres 10, each wall comprises here an external protective layer 3 and a dividing layer, formed of chemically inert, porous fibres 2. The support 5 is attached against a wall 7 by one of its walls 4, by conventional means, perfectly within the scope of a person skilled in the art. The other wall 4 of the support 5, opposite on the wall 7, has been cut on a horizontal section 21 to be able to remove a part of it, in order to form a pocket 31 for receiving the plant 11.

[0027] An irrigation device 9 is provided, above the pocket 31 and, below the pocket 31, a container for collecting the drained water. The water from the irrigation device 9 flows along the support 5 under the effect of gravity through the pores of the layers of the walls 4, 4. The irrigation system can be a drop-by-drop system or an intermittent system. It will be noted that it is by simplicity and clarity, that a support 5 with one single pocket 31 has been defined. It is naturally easy to provide a support with a plurality, even a large plurality of growing pockets. Here, a totally draining growing support is made use of, in other words, of which the water retention properties are very weak, even non-existent. This enables a better development of the root system 12 of the plant 11 in the draining support 5. That, combined with the presence of pores in the walls 4, 4 of the support 5, ensures it a better mechanical holding.

[0028] Thanks to the low proportion of biodegradable fibres 10 in the draining layers 1 of the porous support 5, here, slowly biodegradable fibres like hemp or coconut fibres, a better colonisation is obtained by fungi and/or microorganisms, in particular aerobic fungi and/or microorganisms, which has a usefulness in itself for the growing of these fungi and/or microorganisms, and improves the metabolism of the roots 12 of the grown plant 11.

[0029] Organic fertilisers (here coming from plant waste, other than waste from the grown plant) have been used, the support 5 allowing the presence of aerobic fungi and/or microorganisms.

[0030] The internal, draining, porous layer 1 is here produced, mainly, from synthetic fibres, such as polyolefins, in particular, polypropylene.

[0031] The fibres forming the internal, porous and draining layer 1 are, mainly, not biodegradable and are chemically inert, at least under the conditions of temperature and pH level, where organisms are grown. These fibres are chemically resistant to the metabolites secreted by the growth or to the substances present in fertilisers. Furthermore, these fibres do not supply nutrients to the grown organisms. However, these fibres serve as a physical support for the growing of these grown microorganisms.

[0032] The internal, porous and draining layer (1) comprises here a small proportion, between 2 and 5% of 10%, of a biodegradable fibre, preferably slowly biodegradable, like a hemp or coco fibre. By slowly biodegradable fibre, this means fibres which are totally degraded by organisms in the environment (for example, the grown plant, fungus and/or microorganism, and/or ambient or added microorganisms) over 10 months old, preferably over 20 months old, but preferably also less than 60 months old. The presence of these fibres increases the fungi and/or microorganism biomass in the porous support of the invention.

[0033] Fibres forming the porous, draining layers 1 and 2 of the walls 4 and 4 of the support 5 can be weaved or knitted, or again form a non-woven textile and/or a meshed network. These layers 1 and 2 therefore have a certain thickness and an internal porosity; their structure is continuous and non-perforated. Thus, even if the porous, draining layers 1 and 2 are made from polyolefins, they differ from a perforated plastic, made from polyolefins; their thickness and their porosity allow the roots 12 of the plant to cling on to, in and/or between the porous, draining layers 1 and 2.

[0034] The layers 1 and 2 produced contain a large number of gaps. These pores allow water and air to circulate. Thus, these layers 1 and 2 are not, or are not very, hygroscopic.

[0035] The porous, draining support 5 of this application, is good for growing an organism, this includes a plant organism, because it contains significantly more atmospheric oxygen and allows a better colonisation by the root system, as well as a colonisation by the fungi and/or microorganisms.

[0036] This colonisation does not prevent the draining of irrigation water, even over time, in other word, a significant proportion of pores remains, the pores not being obstructed because of this colonisation.

[0037] A vertical support 5 has been considered. It can also be tilted vertically, so that the irrigation water flows under the effect of gravity.

[0038] The different layers of the walls 4, 4 are assembled on top of each other by known means, such as sewing or stapling. These layers can be connected 1) at their ends (top, bottom) or on their lateral periphery, 2) at the points of mechanical tension around the pocket 31 (particularly at the bottom and at the top) where the plant 11 to be grown is located, or 3) over the whole of their surface.

[0039] In reference to FIG. 3, the growing support 6 only comprises one single wall 14. The wall 14 is substantially horizontal. It comprises a top layer 41 which is porous, mainly inert, and draining. Its characteristics are the same as those of the internal layer 1 of the support 5 in FIGS. 1 and 2, with the same provisions and the same options. The wall 14 comprises here a bottom layer 42, the same characteristics and options as the dividing layer 2 of the support 5 in FIGS. 1 and 2.

[0040] The support 6, however, does not comprise any organism receiving pocket, but the same organisms can be grown there as on the two-walled support 5. It is connected to a support device, shown here on the trestles 45 and irrigation water collector 46. The irrigation system is not represented in FIG. 3.

[0041] This invention allows the growing of aerobic fungi and/or microorganisms. This growing of aerobic fungi and/or microorganisms can, in practice, be a combined growing with plants, which allows a symbiosis at the level of the plant roots (the plant benefits from the fungus and/or the microorganism, and vice versa), or again, modify the secondary metabolism of the plant, even the fungus and/or microorganism up to optimising the production of desired metabolites.

[0042] The method of purifying biological waste consists of preparing a growing support with one or two walls, such as, preferably, a growing support containing the porous layer comprising biodegradable fibres, seeding this support with plants and/or (aerobic) fungi and/or (aerobic) microorganisms, and irrigating this seeded support with biological waste. This waste, which can comprise one or several peptides and/or metabolites of it, nucleic acids and/or metabolites of it, polysaccharides and/or metabolites of it, must be compatible with the metabolism of the organisms grown on this support, or made compatible with the metabolism of the organisms grown. For example, the biological waste to be purified can be diluted or mixed with other biological waste and/or other nutrients so that its different components correspond to the metabolism of the species grown (nitrogenous compound content, sugar content, mineral content). The possible presence of toxic compounds for the (combined) growth, should be controlled, and, if needed, adapted (selective extraction, dilution of the composition, adjustment of pH level). A person skilled in the art is able to adapt the flow of waste, so as to maintain the (combined) growth over time, while eliminating (biological) waste as much as possible because of the metabolism of the grown organisms.