WO2022200391A1 - Propagation de plante - Google Patents

Propagation de plante Download PDF

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Publication number
WO2022200391A1
WO2022200391A1 PCT/EP2022/057558 EP2022057558W WO2022200391A1 WO 2022200391 A1 WO2022200391 A1 WO 2022200391A1 EP 2022057558 W EP2022057558 W EP 2022057558W WO 2022200391 A1 WO2022200391 A1 WO 2022200391A1
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WO
WIPO (PCT)
Prior art keywords
plant
shell
capsule
optionally
cover
Prior art date
Application number
PCT/EP2022/057558
Other languages
English (en)
Inventor
Fred GREEN
Nigel EBBLEWHITE
Original Assignee
Epigenetica Limited
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Epigenetica Limited filed Critical Epigenetica Limited
Priority to GB2316120.1A priority Critical patent/GB2620338A/en
Publication of WO2022200391A1 publication Critical patent/WO2022200391A1/fr

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Classifications

    • AHUMAN NECESSITIES
    • A01AGRICULTURE; FORESTRY; ANIMAL HUSBANDRY; HUNTING; TRAPPING; FISHING
    • A01CPLANTING; SOWING; FERTILISING
    • A01C1/00Apparatus, or methods of use thereof, for testing or treating seed, roots, or the like, prior to sowing or planting
    • A01C1/04Arranging seed on carriers, e.g. on tapes, on cords ; Carrier compositions
    • AHUMAN NECESSITIES
    • A01AGRICULTURE; FORESTRY; ANIMAL HUSBANDRY; HUNTING; TRAPPING; FISHING
    • A01GHORTICULTURE; CULTIVATION OF VEGETABLES, FLOWERS, RICE, FRUIT, VINES, HOPS OR SEAWEED; FORESTRY; WATERING
    • A01G31/00Soilless cultivation, e.g. hydroponics
    • AHUMAN NECESSITIES
    • A01AGRICULTURE; FORESTRY; ANIMAL HUSBANDRY; HUNTING; TRAPPING; FISHING
    • A01GHORTICULTURE; CULTIVATION OF VEGETABLES, FLOWERS, RICE, FRUIT, VINES, HOPS OR SEAWEED; FORESTRY; WATERING
    • A01G31/00Soilless cultivation, e.g. hydroponics
    • A01G31/02Special apparatus therefor
    • AHUMAN NECESSITIES
    • A01AGRICULTURE; FORESTRY; ANIMAL HUSBANDRY; HUNTING; TRAPPING; FISHING
    • A01GHORTICULTURE; CULTIVATION OF VEGETABLES, FLOWERS, RICE, FRUIT, VINES, HOPS OR SEAWEED; FORESTRY; WATERING
    • A01G9/00Cultivation in receptacles, forcing-frames or greenhouses; Edging for beds, lawn or the like
    • A01G9/02Receptacles, e.g. flower-pots or boxes; Glasses for cultivating flowers
    • A01G9/029Receptacles for seedlings
    • A01G9/0293Seed or shoot receptacles

Definitions

  • the present invention relates to plant propagation.
  • the present invention relates to a plant growing or propagation system, to materials and apparatus for use in the system and to methods using the system.
  • a single plant is grown in its own module or pod of plant growth material, such as soil, peat or coir, to allow the plant to develop its own root system without competition for resources from adjacent plants.
  • plant growth material such as soil, peat or coir
  • Such modular systems use an arrangement of injection-moulded plastic trays having an array of cells, each cell associated with a single plant.
  • multiple seeds may initially be sown in each cell, for thinning out or pricking out.
  • Such systems are cost-effective but suffer from a number of disadvantages.
  • One significant disadvantage is that it is not possible to see the root system. As such, the grower cannot be certain that a plant has a sufficiently well-developed root system to be ready for growing on.
  • An effective alternative system employs fibre pots, in which the plant is grown initially in a growing medium placed in a fibre pot formed of a biodegradable wood-pulp. When potting up, the plant, its plant growing medium and the fibre pot are placed into a larger pot of growing medium. Over time, the fibre pot decomposes and the roots grow out into the larger pot.
  • Jiffy Pellets and Jiffy Growblock trade marks are available from Jiffy Group, which has also developed an alternative approach in which a module of growing medium is provided in a mesh bag having an aperture in the top through which the stem of a plant is able to grow.
  • This system is sold under the Jiffy Pellets and Jiffy Growblock trade marks.
  • the mesh bag is formed of polypropylene or polyethylene, meaning that the product relies on growing roots penetrating the mesh during development.
  • Other versions use polylactic acid for the polymer for the mesh, such that the mesh is decomposable over time.
  • Jiffy Pellets and Jiffy Growblocks are supplied as dried, highly compressed discs of growth medium which must be watered to reconstitute the product into a useable growing module.
  • US 10,398,091 describes an alternative plant growing container having a generally conventional plant pot holding a plant growth medium and in which a seed may be sown or in which a growing plant is potted.
  • the container includes a pliable cover having an aperture through which the stem of a growing plant may grow.
  • the aperture is initially smaller than the expected crown of the plant at its mature stage of growth.
  • the pliable cover is made of a material which allows the growing plant stem to increase the area of the aperture as the plant grows, whilst maintaining a substantially sealing contact between the aperture and the stem, such that the cover creates a moisture barrier between the interior and the exterior of the container.
  • Micro holes may be provided in the base or walls of the container to allow nutrient fluid to enter the container; the micro holes are designed to prevent plant roots penetrating from the interior of the container.
  • a further alternative system particularly suitable for hydroponic plant cultivation systems, involves the use of blocks of mineral wool as the medium in which the roots of the plant develop.
  • a plug-germinated plant is placed into a cavity preformed in an upper surface of a block of mineral wool, such as stone wool.
  • the cavity is shaped and dimensioned to correspond with the shape and dimension of the plug.
  • Series of blocks of increasing sizes are available such that established plants may be transplanted in a conventional manner into larger blocks as their root systems grow. Some plants fail to thrive when grown in mineral wool blocks and the blocks are not biodegradable.
  • WO 2020/018993 describes a semi-automated plant growing system for growing-on plants, which comprises a container configured to hold a living plant root mass in a growth medium.
  • the container has a pliable cover which comprises a hole to permit the shoot of a growing plant to pass through.
  • the container has openings in its base or walls to permit fluid communication with a nutrient solution. The holes must be sufficiently small to prevent plant roots passing through.
  • Young plants are introduced into the system at a loading stage and transported through the system in a conveyor-type assembly. As the plants move through the system, they are exposed to water and nutrient supplies and to light.
  • the system further includes a plant unloading stage at which grown plants are removed from the system.
  • US 2017/020095 proposes a system in which a coco pod is provided, the pod having at least one layer of coconut coir fibre and a hole for receiving a plant's roots.
  • the system includes a nutrient solution, and a container for holding the coco pod and the nutrient solution, such that the coco pod is at least partially immersed in the nutrient solution and the plant's roots are continuously exposed to the nutrient solution and substantially protected from sunlight.
  • the present invention seeks to provide an alternative approach to plant propagation systems, in particular to provide apparatus and systems which provide a clean or sterile growing environment and are suitable for automation.
  • the present invention provides a system for growing a plant, the system comprising a plant propagation material and a capsule for growing the plant propagation material, wherein the capsule comprises: a shell; a cover sealed to the shell thereby defining a cavity; a plant growing medium for receiving plant propagation material, the plant growing medium being reliably contained within the cavity; and a root aperture formed or formable in the shell, such that, in use of the system, a plant root grows through the root aperture.
  • the plant propagation material is at least one seed or vegetative propagation material, such as a stem or leaf cutting.
  • the system further comprises a mineral nutrient solution, to which, in use of the system, the plant root is exposed.
  • the root aperture is formable by removing a portion of the shell or by puncturing the shell.
  • the shell further comprises a root aperture seal or closure and the root aperture is formable by removing, puncturing or dissolving the root aperture seal or closure, optionally the root aperture seal or closure is a mesh or fabric, optionally a biodegradable mesh or fabric, further optionally a non-woven fabric.
  • the shell is a moulded plastic shell, optionally a biodegradable plastic shell, or a composite material.
  • the shell is formed of a resilient material.
  • the cover is a film, optionally a biodegradable film, a paper sheet or a metal foil, optionally an aluminium foil; further optionally the cover is piercable.
  • the plant growing medium is a coco peat growing medium and/or an agar plant growing medium.
  • the plant growing medium is inoculated with a microbial volatile organic compound-producing organism, optionally Cladosporium sphaerospermum strain TC09.
  • the capsule is provided with a machine-readable label.
  • the label indicates at least one of: a name of the plant, and an orientation for the capsule; optionally wherein the machine-readable label is a coded machine-readable label; further optionally wherein the coded machine-readable label is a barcode or QR code.
  • the capsule is further provided with a machine-readable tag, optionally a RFID tag.
  • a seed is provided to the plant growing medium by: (i) applying or inserting the seed into the plant growth medium prior to sealing the cover to the shell, or (ii) piercing the cover or shell and inserting the seed into the plant growth medium through the cover.
  • the system further comprises a needle seeder apparatus coupled to a seed reservoir, wherein the apparatus is arranged such that, in use, a needle seeder places one or more seeds from a reservoir of seeds in the seed reservoir into the plant growing medium in the cavity by piecing the cover or shell.
  • the plant propagation material is a vegetative propagation material in the form of a plant cutting.
  • the cover is piercable such that the plant cutting is provided to the plant growing medium by piercing the cover and inserting the cutting into the plant growing medium through the cover.
  • the system further comprises a transportation module comprising a sleeve to receive the capsule and the plant, optionally wherein the sleeve comprises a retaining portion for retaining the plant root within the sleeve, optionally the retaining portion comprises a water reservoir for providing water and, further optionally, nutrients to the plant root.
  • the system further comprises a plant cutting apparatus for obtaining a plant cutting from a plant and a transplanting apparatus to transplant the plant cutting into the capsule by piercing the cover of the capsule and inserting the cutting into the plant growing medium through the cover.
  • the shell of the capsule is provided with a lip, rim or flange to engage with robotic devices.
  • the system further comprises a capsule manipulation assembly for placing a plurality of capsules into an array, the array having a capsule density, whereby in use, the capsules are manipulated to reduce the capsule density of the array to provide additional space around each capsule for plant growth.
  • the system further comprises a generator apparatus for generating micro- and/or nano-bubbles from at least one gas and introducing the micro- and/or nano bubbles to a mineral nutrient solution to which the plant root is exposed.
  • a generator apparatus for generating micro- and/or nano-bubbles from at least one gas and introducing the micro- and/or nano bubbles to a mineral nutrient solution to which the plant root is exposed.
  • at least 50%, of the micro- and/or nano-bubbles generated have a diameter of less than 1000nm, optionally less than 500 nm, optionally less than 60 nm or less, optionally 20 nm or less.
  • the micro- and/or nano-bubbles are generated in the presence of one or a mixture of gases selected from oxygen, nitrogen, CO2 and air.
  • the system further comprises means for admixing the micro- or nano bubbles with one or more compounds capable of inducing a change in a phenotype or a physiology of a plant.
  • system further comprises means for adding a microbial volatile organic compound to the micro- and/or nano-bubbles, optionally Cladospoium sphaerospermum strain TC09, to the micro- and/or nano-bubbles.
  • a microbial volatile organic compound to the micro- and/or nano-bubbles, optionally Cladospoium sphaerospermum strain TC09, to the micro- and/or nano-bubbles.
  • the present invention provides a plant propagation capsule comprising: a shell; a cover, the cover being sealed to the shell thereby defining a cavity; a plant growing medium, the plant growing medium being reliably contained within the cavity; and a root aperture formed or formable in the shell, through which root aperture a plant root can grow during use of the capsule.
  • the root aperture is formable by removing a portion of the shell or by puncturing the shell.
  • the shell further comprises a root aperture seal or closure and the root aperture is formable by removing, puncturing or dissolving the root aperture seal or closure, optionally the root aperture seal or closure is a mesh or fabric, optionally a non-woven fabric; further optionally a biodegradable mesh or fabric.
  • the cover is a film, preferably a biodegradable film, a paper sheet, or a metal foil, optionally aluminium foil.
  • the cover is piercable such that the plant propagation material, optionally a seed or plant cutting, can be inserted into the plant growing medium through an aperture pierced into the cover.
  • the plant growing medium is a coco peat growing medium and/or an agar plant growing medium.
  • the plant growing medium is inoculated with a microbial volatile organic compound-producing organism, optionally Cladosporium sphaerospermum strain TC09.
  • the capsule is provided with a computer-readable label.
  • the label indicates at least one of a name of the plant and an orientation for the capsule; optionally the computer-readable label is a coded computer-readable label; further optionally the coded computer-readable label barcode or QR code.
  • the shell of the capsule is provided with a lip, rim or flange to engage with robotic devices.
  • the shell is formed of a resilient material.
  • the present invention provides a method of preparing a packaged plant propagation material, the method comprising the steps of: i) providing a biodegradable shell having a neck defining an opening to the shell and a shell wall comprising a plurality of apertures formed or formable therein; ii) positioning a biodegradable net or mesh into the shell to contact the plurality of apertures; iii) dispensing a quantity of plant growing medium into the net or mesh in the shell; iv) sealing the shell; and v) placing at least one plant propagation material into the plant growing medium.
  • the quantity of plant growing medium is a metered quantity of plant growing medium.
  • the present invention provides a method of producing a plant growing capsule, the method comprising the steps of: i) providing a shell having a neck defining an opening to the shell and a shell wall, defining a cavity; ii) dispensing a metered quantity of plant growing medium into the cavity; and iii) sealing the shell, thereby reliably containing the plant growing medium within the cavity.
  • the metered quantity is dispensed with an apparatus comprising a reservoir for storage of the plant growing medium and a volumetric metering device in fluid communication with the reservoir.
  • the step of sealing the shell comprises applying a seal or cover to the neck of the shell.
  • the step of sealing the shell comprises sealing the shell with a film or foil material.
  • the cover is at least one layer of a film, preferably a biodegradable film, optionally a polylactic acid film; a paper sheet; or a metal foil, optionally an aluminium foil; optionally wherein the cover is piercable.
  • a film preferably a biodegradable film, optionally a polylactic acid film; a paper sheet; or a metal foil, optionally an aluminium foil; optionally wherein the cover is piercable.
  • the cover is formed of a material acting as a fungal spore filter.
  • At least one seed is placed into the plant growing medium prior to sealing the shell.
  • At least one seed is placed into the plant growing medium after sealing the shell by piercing the cover, optionally, the seed is placed using a needle seeder.
  • a plant cutting is placed into the plant growing medium after sealing the shell by piercing the cover.
  • the method further comprises adding water and/or at least one plant nutrient to the plant growing medium.
  • the plant growing medium is a coco peat growing medium and/or an agar plant growing medium.
  • the present invention provides a method of growing a plant, the method comprising the steps of: (i) providing a capsule having a shell, and a cover sealable to the shell, thereby defining a cavity; (ii) substantially filling the cavity with a plant growing medium; (iii) sealing the cover to the shell, (iv) providing at least one plant propagation material in the plant growing medium by piercing the cover; (v) growing a plant from the plant propagation material, whereby a stem of the plant grows through the cover; (vi) forming or providing a root aperture in the shell; and (vii) allowing a plant root to grow through the root aperture.
  • the method further comprises exposing the plant root to a mineral nutrient solution.
  • the root aperture is formed by removal of a portion of the shell or by puncturing the shell.
  • the shell further comprises a root aperture seal and the root aperture is formed by removing, puncturing or dissolving the root aperture seal, optionally the root aperture seal is a mesh, optionally a biodegradable mesh.
  • the plant propagation material is a seed or a plant cutting.
  • the step of providing at least one plant propagation material comprises: (i) placing a seed in the plant growing medium prior to sealing the cover to the shell; or (ii) piercing the cover or shell to insert the seed into the plant growth medium.
  • the step of providing at least one plant propagation material comprises piercing the cover and inserting a vegetative plant material such as a plant cutting into the plant growing medium.
  • the plant growing medium is inoculated with a microbial volatile organic compound-producing organism, optionally Cladosporium sphaerospermum strain TC09.
  • the capsule is a capsule as defined above or a capsule obtainable by the methods described above.
  • the method further comprises the step of providing a sleeve to receive the capsule and the plant, optionally wherein the sleeve comprises a retaining portion for retaining the plant root within the sleeve, optionally the retaining portion comprises a water reservoir for providing water to the plant root.
  • the method further comprises the steps of: (i) providing a plurality of capsules in an array having a capsule density; and (ii) manipulating the capsules at a point during the step of growing the plants, to reduce the capsule density of the array to provide additional space for the plants to grow.
  • the method further comprises the step of generating micro- and/or nano-bubbles from at least one gas and introducing the micro- and/or nano-bubbles to a mineral nutrient solution to which the plant root is exposed.
  • at least 50%, of the micro- and/or nano-bubbles generated have a diameter of less than 1000nm, optionally less than 500 nm, optionally less than 60 nm of less, optionally 20 nm or less.
  • the micro- and/or nano-bubbles are generated in the presence of one or a mixture of gases selected from oxygen, nitrogen, CO2, or air.
  • the micro- or nano-bubbles are admixed with one or more compounds capable of inducing a change in a phenotype or physiology of the plant.
  • the method further comprises the step of adding a microbial volatile organic compound producing organism, optionally Cladosporium sphaerospermum strain TC09, to the micro- and/or nano-bubbles.
  • a microbial volatile organic compound producing organism optionally Cladosporium sphaerospermum strain TC09
  • a plant growth system comprising a plant cutting apparatus for obtaining a plant cutting from a plant and a transplanting apparatus to transplant the plant cutting into a capsule as defined above.
  • the shell is provided with a flange.
  • the shell has a neck portion defining an opening to the shell and the flange is provided adjacent the neck portion or intermediate or between the neck portion and a base of the shell.
  • Figure 1 is an exploded perspective view showing the principal elements of a first embodiment of a capsule in accordance with the present invention
  • Figure 2 is a perspective view of a second embodiment of a capsule in accordance with the present invention.
  • Figure 3 is a perspective view of a third embodiment of a capsule in accordance with the present invention.
  • Figure 4 shows several variations of a fourth embodiment of a capsule in accordance with the present invention.
  • FIG. 1 is a perspective view showing the principle elements of an embodiment of a capsule 10 in accordance with the present invention.
  • Capsule 10 includes a shell 11 having an opening and defining a cavity for a plant growing medium 12.
  • Capsule 10 includes a cover 13 which is sealed to shell 11.
  • Cover 13 may be sealed to shell 11 by any suitable means compatible with materials used, such as adhesive and ultrasonic welding, for example.
  • the opening of shell 11 includes a flange, lip or rim 14 which provides a surface against which cover 13 seals and which provides a surface to aid manipulation of the capsule, particularly by robotic devices.
  • Capsule 10 is of circular cross-section but other shapes are equally suitable, including square or other polygonal shapes.
  • shell 11 has a frusto-conical wall or walls which taper inwardly from rim 14 of the shell to base 15 of the shell.
  • Plant growing medium 12 retains plant propagation material, in use of the capsule. For example, a seed or a plant cutting is placed into plant growing medium 12.
  • Shell 11 is, prior to use, sealed such that plant growing medium 12 is reliably retained within the cavity of the shell.
  • Medium 12 is also protected from contamination or changes in its condition, such as uptake or loss of water.
  • Sterilised growing media can retain sterility and moisture content.
  • the root aperture Prior to use of the capsule, the root aperture is closed. The root aperture may be maintained in a closed configuration during a germination stage or during an initial stage of plant growth after placement of a plant cutting in medium 12, to retain moisture within plant growing medium 12 and to retain plant growing medium 12 within capsule 10 until the root system of the plant has developed sufficiently that the roots develop a root network sufficient to retain plant growing medium 12 within the developing network of roots.
  • a root aperture is formable in shell 11 of capsule 10.
  • the root aperture may be formed within the body of shell 11 and may provide a removable closure or seal to the capsule, which closure or seal overlies an open portion of the body of shell 11 , or may be formed by puncturing the material of shell 11 or removal of a portion of shell 11, for example by means of a frangible portion to shell 11.
  • the removable closure or seal is formed of a dissolvable or rapidly biodegradable material occluding the root aperture such that the root aperture opens gradually, without requiring user intervention, as the occluding material dissolves or degrades and as the root system grows.
  • a dissolvable or rapidly biodegradable material occluding the root aperture such that the root aperture opens gradually, without requiring user intervention, as the occluding material dissolves or degrades and as the root system grows.
  • the root aperture allows roots of the growing plant to continue to grow externally from plant growing medium 12.
  • the root aperture may be a single aperture and may be formed in a base 15 of shell 11.
  • the root aperture is a plurality of apertures formed in at least a lower portion of shell 11, such as base 15 and at least the lower portion of the walls of shell 11.
  • the plurality of apertures may be selectively openable such that one aperture or a group of apertures may be opened initially and selectively more apertures opened as plant growth progresses.
  • Shell 11 could be formed as a basket or with a mesh or net construction.
  • the shell has a moulded construction, suitably a moulded or shaped plastic, metal or composite material.
  • the shell is formed of a biodegradable material, such as a biodegradable plastic, preferably a compostable plastic, such as polylactic acid.
  • shell 11 includes a liner (not shown) to aid in retaining plant growing medium 12.
  • the liner is advantageously formed of a biodegradable woven or non-woven mesh or fabric.
  • Cover 13 is formed of a material which is compatible with the material of shell 11 and is conveniently formed as a film or mesh, optionally two or more overlayered layers of film or mesh. Suitable materials include biodegradable plastic films, paper or metal films, such as aluminium film. Polylactic acid film is particularly suitable and, as a polylactic acid mesh or non-woven fabric, has been observed to act as a fungal spore filter, allowing volatile organic compounds present in the plant growing medium to pass through the cover, providing further advantages as discussed above.
  • cover 13 is applied to shell 11 such that cover 13 is taut across the opening to the cavity, to aid, where required, piercing of the cover by being able to withstand the pressure of a needle seeder or other piercing apparatus, for example.
  • Assembled capsules may be subjected to a sterilisation procedure, suitably by autoclaving.
  • the shell is formed of a material which shrinks slightly when exposed to heat, causing the shell to shrink and compress the contained growing medium.
  • Plant growing medium 12 is chosen having regard to the growing requirements of the plant with which the system will be used.
  • plant growing medium 12 may include a coco peat growing medium, an agar plant growing medium and/or a loam-based compost or mixtures thereof.
  • the root aperture arrangement of the capsules of the present invention provides ease of access to the root zone of the plant. This is highly advantageous in particular environments. For example, where access to the root system is required for application of compounds to enhance or influence growth or induce a change in the phenotype, genotype or chemistry of the plant.
  • one or more microbial volatile organic compound (MVOC) is applied to the roots of the plant.
  • MVOC microbial volatile organic compound
  • all the materials from which the capsule are made are biodegradable, preferably compostable.
  • Figure 2 shows a capsule 20 having a shell 21 and a cover 22 applied thereto as described above.
  • Shell 21 is formed having a grid-like skeleton of horizontal 23 and vertical 24 ribs forming apertures 25 therebetween. Corresponding ribs (not shown) are formed in the base of shell 21. Prior to use, apertures 25 are closed, suitably by means of a tape or cover (not shown) adhered or otherwise applied to shell 21.
  • Shell 21 is suitably formed from a plastics material, for example by injection moulding.
  • Figure 3 shows a capsule 30 having a shell 31 and cover 32 applied thereto as described above.
  • a lower portion of shell 31 is formed with a mesh or net-like structure of apertures 33, defining the root aperture, and an upper portion of the shell has a neck portion 34.
  • the mesh or net-like structure 33 extends to the lip or rim of the shell.
  • a removable closure is provided to provide an initial closure to the apertures, which may conveniently be a dissolvable or biodegradable composition.
  • Embodiments having this type of construction may be formed as a single injection moulded plastics unit in which the mesh or net-like structure is co-moulded with neck portion 34 or with the lip or rim.
  • the mesh or net-like structure defining the root aperture may be formed of a woven or non-woven fabric mounted to the neck portion 34 or to the lip or rim.
  • a closure film may be applied to the fabric to close the root aperture or the fabric may be impregnated with a dissolvable or degradable composition as described above.
  • FIG. 4 shows an inverted capsule 40 having a frusto-conical wall 41 , tapering towards a base 42.
  • base 42 includes a root aperture in the form of a single, central aperture 43(a).
  • base 42 includes a plurality of elongate slots 43(b) similar to those described above with respect to the embodiment of Figure 2.
  • Figure 4(c) shows a base 43(c) having a mesh or net-like structure as described above with respect to the embodiment of Figure 3.
  • the root aperture arrangement is restricted to the base of the shell. In other embodiments, the root aperture arrangement is provided in both the walls and base of the shell.
  • a principle advantage of the root aperture arrangement of the capsules of the present invention is to provide ease of access to the root zone of the plant for allowing the introduction of compounds, especially via a nanobubble mixture, such as microbial volatile organic compounds or nucleic acids, at any stage of the germination and growth of the plant.
  • a seed of the desired plant variety is sown into the plant growth medium at the manufacturing stage.
  • the seed may be sown prior to application of cover 22, 32 or may be sown after application of the cover, through the cover, using a needle seeder, for example.
  • a needle seeder for example.
  • the combination of a needle seeder and capsules forms a further aspect of the system of the present invention.
  • plant growing medium 12 is introduced to capsule 10 in a metered or dosed fashion.
  • Conventional methods of mechanising plant pot filling involve passing plant pots under a continuous flow of compost to over-fill the pot with compost and then passing the pot under a horizontal blade which removes excess compost. Excess compost is collected and recirculated for reuse.
  • a metering or dosing apparatus can be provided with a reservoir for storage of the material to be dispensed.
  • the reservoir feeds the material into a metering chamber, typically under gravity or by means of a delivery device such as a screw pump or the use of positive air pressure.
  • the metering chamber may include a rotatable subassembly comprising a plurality of sub-chambers, each of which has the same volume, thereby defining the metered volume, and each of which is fed with the material from the reservoir. Rotation of the subassembly causes each sub-chamber, in turn, to align with an outlet through which the material to be dispensed falls under gravity.
  • each shell is filled fully with plant growing medium 12 and cover 13 is sealed to shell 11 in an automated process.
  • a capsule of the present invention By use of metered dosing of plant growing medium into a capsule of the present invention, greater control can be maintained over the quality of the medium. Additionally, by providing a capsule in accordance with the present invention, the plant growing medium is retained within the capsule throughout the plant growing and harvesting process, such that the entire system has the capability to remain clean and sterile from start to finish.
  • capsule 10 with sealed cover 13 and rim 14 provides significant advantages to a propagation system since plant growing medium 12 is fully contained, such that capsule 10 can be manipulated without loss of plant growing medium 12, maintaining a clean propagation system, combined with access to root systems, which provides the additional advantages discussed herein.
  • the present invention provides packaged plant propagation products which, as a result of the controlled metering and the sealing of the capsule are able to maintain uniformity between capsules and sterility of the growing medium up to the point at which the capsule is prepared for seed germination or insertion of a plant cutting. This leads to an improvement in plant viability and a reduction in plant growth variability, which is particularly advantageous.
  • capsules produced by this method are able to have a long storage-life.
  • the entire plant growing process can be more carefully controlled, especially as regards sterility and hygiene, from start to finish, from preparation of the plant growing medium, shell-filling, seeding or planting a plant cutting, spacing out, growing on, and harvesting or sale as a living plant.
  • the capsules and systems of the present invention provide the means for a propagation method comprising a first step of producing a sealed capsule.
  • the sealed capsules have particular advantages in propagation methods which require or benefit from a clean or sterile environment. Examples of such methods are provided herein.
  • a plurality of sealed capsules is prepared by filling the cavity of each capsule with a metered amount of sterile coco peat using an automated dispensing and sealing apparatus, as discussed above. The coco peat is then reliably contained within the capsule throughout the plant growing protocol, thereby allowing for a sterile plant growth protocol.
  • the capsules are contained within an array or tray.
  • the array is sited in a vertical farm under controlled environment conditions.
  • a seed is placed into the coco peat contained within the capsule by piercing the cover of the sealed capsule, using a needle seeder apparatus, for example.
  • the seeds germinate.
  • the stem of each seedling grows through the cover of the sealed capsule. If appropriate, the cover can be pierced at a suitable time to allow the stem to grow through the cover.
  • each capsule in the array is pierced and a plant cutting, such as a stem or leaf cutting, is inserted into the plant growth medium through the pierced cover.
  • a root aperture is provided in the sealed capsule to allow the roots of the growing plant to penetrate from the sealed capsule as they grow.
  • the exposed roots are provided with a mineral nutrient solution as part of a hydroponic system.
  • the solution can be provided with nanobubbles, optionally admixed with a compound capable of inducing a change in the phenotype, genotype, chemistry or physiology of the growing plant.
  • the capsules are robotically spread out within the array to reduce their density and to provide additional space for the plants to grow.
  • Each capsule comprises a resilient flange for automated robotic movement of the capsules within or outside the array.
  • the capsules and the plants contained therein are packaged for transportation by automated robotic movement of the capsules by engagement with the flange, from the array into suitable packaging.
  • the capsules of the present invention are advantageous for use in methods involving automated transplanting or sticking processes and apparatus. Since the capsules reliably contain plant growth medium within a sealed cavity and since the capsules can be provided with a flange to engage robotic devices, use of the capsules enables enhanced robotic manipulation within a propagation procedure.
  • the apparatus combines an automated or mechanised vegetative propagation material cutter, to remove a cutting from a mother plant, with the transplanting or sticking functionality. This arrangement is particularly advantageous in combination with machine-readable labelling functionality, for tracking lineage of transplanted cuttings.
  • the capsule is additionally provided with a machine-readable label, such as a coded label, conveniently a barcode of QR code.
  • a machine-readable label can provide an identification of the plant variety.
  • the label can also provide an indication of the correct orientation of the capsule.
  • the labelling can assist in mechanised manipulation of the capsules, both at the initial germination stage and at later stages. For example, if it is possible to know and maintain the orientation of a capsule, high speed cutting of the plant can be made more accurate.
  • Providing plant modules in a modular plant propagation system with a machine-readable label forms another distinct aspect of the present invention.
  • the plant propagation system of the present invention is highly advantageous in soil-less growth systems, such as hydroponic, aquaponic and aeroponic growth systems, which allow plant growth under controlled conditions, and in vertical farming installations.
  • hydroponic systems the roots of a growing plant are provided with water and nutrients without the use of soil or similar growth medium.
  • the roots of the plant are exposed and sit in a water supply which contains a mineral nutrient mixture, typically containing sources of nitrogen, phosphorus and potassium, considered essential for the growth of plants, and calcium, magnesium and iron.
  • a mineral nutrient mixture typically containing sources of nitrogen, phosphorus and potassium, considered essential for the growth of plants, and calcium, magnesium and iron.
  • Such nutrient mixtures are well-known in the art and will not be described further here.
  • Such hydroponic systems can further incorporate, for example, nanobubble technology to enhance plant growth or to deliver specific compounds to the plant roots, as discussed further below.
  • the system of the present invention provides advantages to each of these growth systems in providing and maintaining a clean growing environment and in allowing automation at various stages of plant propagation. Accordingly, in a further aspect, the system of the present invention includes a hydroponic growth system including one or more capsules of the invention.
  • the capsules of the present invention provide a highly convenient method for transferring plants from the germination and/or initial growth stage to a hydroponic growth system.
  • the capsule provides a resilient container for an automated mechanised transfer system to transfer growing plants into a hydroponic growth system without needing to contact the growing plant and without risking damage to the growing root system.
  • the lip or rim to the shell forms a flange against which a collector of an automated plant transfer apparatus can bear to pick up and transfer the capsule from one area to another.
  • a flange may be formed at a point intermediate or between the top of the shell and the base of the shell.
  • the system of the present invention includes, in some embodiments, a transfer apparatus for transferring capsules from a plant germination and/or growth station to a hydroponic growth system.
  • the system further comprises a tray having a plurality of apertures, each aperture shaped and dimensioned to receive a respective capsule.
  • the hydroponic growth system includes a system of introduction of oxygen to the water of the hydroponic system in the form of nano- and/or microbubbles.
  • nano- or microbubbles also referred to as ultrafine bubbles
  • WO2017/156410 discusses providing a composition containing nanobubbles dispersed in a liquid carrier with another liquid to create an oxygen-enriched composition that is then applied to plant roots. Such a composition can promote germination or growth of plant seedlings.
  • EP2460582 discusses the production of super-micro bubbles of several hundred nm to several dozen pm in size (diameter) and ways in which such bubbles can be provided.
  • EP3721979 relates to a charged nanobubble dispersion liquid, a manufacturing method thereof and manufacturing apparatus therefor, and a method to control the growth rate of microorganisms and plants using nanobubble dispersion liquid.
  • the microbubbles and / or nanobubbles may be generated using one or a mixture of gases.
  • the gas may be selected from the group comprising or consisting of air, oxygen, carbon dioxide, nitrogen, hydrogen, ethylene, ethylene oxide and combinations thereof.
  • the microbubbles or nanobubbles may be generated in the presence of oxygen to provide an oxygen-enriched liquid, which may then be applied to plant roots.
  • the microbubbles or nanobubbles may be provided by any method as known in the art including swirl-type liquid flow, venturi, high-pressure dissolution, ejector, mixed vapour direct contact condensation and supersonic vibration.
  • any method as known in the art including swirl-type liquid flow, venturi, high-pressure dissolution, ejector, mixed vapour direct contact condensation and supersonic vibration.
  • spinning a liquid around a motor raising the flow rate of a liquid by pump pressure; providing air or another gas or gasses to the liquid; and stirring the liquid to provide bubbles and then disrupting the bubbles to form microbubbles, or nanobubbles may be used.
  • air or other gas or gasses via a jetting nozzle may be provided to a liquid such that bubbles jetted from the jetting nozzle are torn into super-micro bubbles by the force of jet flow of the liquid jetting nozzle.
  • bubbles may be generated by stirring, and then passing the generated bubbles through the eyes of a mesh membrane to form nanobubbles.
  • a compressor for delivering gas under pressure into liquid and a bubble generation medium may be provided, wherein the bubble generation medium consists of a high-density compound which is an electrically conductive substance.
  • a nanobubble as used in the present invention may have lifetime of at least one hour, at least 2 hours, at least 3 hours, at least 5 hours, at least 1 day, at least 1 week, for at least one month or for at least three months under ambient pressure and temperature.
  • a nanobubble may have high gas solubility into the liquid due to its high internal pressure.
  • a microbubble or nanobubble mixture may be provided, for example a micro- or nano bubble with a bubble diameter of 200nm-10pm.
  • the nanobubbles may be positively or negatively charged nanobubbles.
  • the nanobubbles may have a zeta potential of 10 mV to 200 mV, or -10 mV to -200 mV.
  • the nanobubbles may have a zeta potential of 5 mV to 150 mV, or -5 mV to -150 mV.
  • stability of the nanobubbles may be provided due to negatively charged surfaces of the nanobubble.
  • pH may be used to generate charged micro- or nano-bubbles.
  • a nanobubble refers to a bubble that has a diameter of less than one micron.
  • a microbubble, which is larger than a nanobubble, is a bubble that has a diameter greater than 1 micrometre in diameter.
  • At least 50% of the nanobubbles generated have a diameter of less than 300 nm, suitably 80 nm of less, optionally 20 nm or less.
  • a nanobubble may have a mean diameter less than 500 nm or less than 200 nm, or ranging from about 20 nm to about 500 nm (e.g., from about 75 nm to about 200 nm).
  • a concentration of nanobubbles in a liquid carrier may be at least 100 kilo counts per second (kcps), for example as determined using a Zetasizer (Zetasizer Nano ZS) or suitable apparatus.
  • kcps kilo counts per second
  • a mixture of micro- and / or nanobubbles and a compound capable of inducing a change in the phenotype, genotype chemistry, or physiology of the plant, in particular an epigenetic regulator can be provided to a plant for at least 1 hour, at least 4 hours, at least 12 hours, at least 24 hours, at least 48 hours, at least 7 days, at least 10 days, at least 14 days, at least 20 days, or over the lifetime of the plant.
  • a mixture of micro- and/ or nanobubbles and a compound capable of inducing a change in the phenotype, genotype chemistry, or physiology of the plant, in particular an epigenetic regulator can be provided to a plant for at least 1 hour, at least 4 hours, at least 12 hours each day over the lifetime of the plant.
  • Suitably exposure of the plant to the micro- and / or nanobubble and compound mixture can occur at less than 1 hour post-germination, at 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11 , 12, 13, 14, 15, 16, 17, 18, 19, 20, 21 , 22, 23, or 24 hours post germination, or at 1 , 2, 3, 4, 5, 6, 7, 8, 9, 10, 15, 20, 25, or 30 days post-germination, or at 1 , 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, or 12 months post-germination, or at 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, or more years post-germination.
  • Germination occurs with the emergence of the radicle.
  • the plant growth medium contains additional components which have an effect upon the growing plant.
  • US2020/0045980 discusses the use of one or more volatile organic compounds produced by Cladosporium sphaerospermum to increase at least one growth characteristic in a plant after exposure of the plant to the volatile organic compound(s) (VOCs) wherein the VOC from Cladosporium sphaerospermum were provided to the plant’s headspace.
  • VOCs volatile organic compound(s)
  • Cladosporium sphaerospermum was noted not to be required to grow in the soil with the plant to be treated as, in fact, such growth in soil may result in reduced effects on the plant's phenotype (growth, yield, etc.).
  • the claimed system further includes a sleeve attachable to the capsule to enclose the roots of the growing plant.
  • the sleeve provides a cavity for a reservoir of water, preferably containing a mineral nutrient mixture, to maintain the health of the plant during transportation.
  • the plant may be a culinary or other herb and the packaged plant may be sold in supermarkets as a replacement for the current method of selling growing herbs in which the plant is sold in a small pot of compost.
  • the packaged plant is also very useful as a method of growing plants in a high-density automated system, under ideal growing conditions, prior to selling plants for potting on by commercial or other growers.
  • the term plant includes leaf plants, fruit plants, grains and algae, or mosses and encompasses ornamental and functional plants and may be a seed or another plant part, such as a leaf, a piece of stem, pollen, anther, embryo, or any other stem cells of the plant from which new plants can be grown.
  • a plant tissue may be incubated on solid media containing nanobubbles and compounds to enhance uptake of transformation vectors, etc. into recalcitrant plant species.
  • the plants used may be selected from the group comprising higher or vascular plants adapted to synthesise metabolites in a large quantity.
  • a plant may include hemp, maize/corn, soy, rice, wheat, potato, sugarcane, arbuscular mycorrhiza fungi, tomato, lettuce, microgreens, cabbage, barley, tobacco, pepper, sorghum, cotton, sugar beets, or any other legumes, fruits, nuts, vegetables, pulses, flowers, or other commercial crop not inconsistent with the objectives of this disclosure.
  • a plant may be selected from, without limitation, energy crop plants, plants that are used in agriculture for production of food, fruit, wine, biofuels, fibre, oil, animal feed, plants used in the horticulture, floriculture, landscaping and ornamental industries, and plants used in industrial settings.
  • a plant may comprise gymnosperms and angiosperms, flowering and non flowering. If an angiosperm, the plant can be a monocotyledon or dicotyledon.
  • Non-limiting examples of plants that could be used include desert plants, desert perennials, legumes, (such as Medicago sativa, (alfalfa), Lotus japonicas and other species of Lotus, Melilotus alba (sweet clover), Pisum sativum (pea) and other species of Pisum, Vigna unguiculata (cowpea), Mimosa pudica, Lupinus succulentus (lupine), Macroptilium atropurpureum (siratro), Medicago truncatula, Onobrychis, Vigna, and Trifolium repens (white clover)), com (maize), pepper, tomato, Cucumis (cucumber, muskmelon, etc.), watermelon, Fragaria, other berries, Cucurbita (squash, pumpkin, etc.) lettuces, Daucus (carrots), Brassica, Sinapis, Raphanus, rhubarb, sorghum, miscanthus, sugar

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  • Life Sciences & Earth Sciences (AREA)
  • Environmental Sciences (AREA)
  • Soil Sciences (AREA)
  • Cultivation Receptacles Or Flower-Pots, Or Pots For Seedlings (AREA)

Abstract

La présente invention concerne la propagation de plante. En particulier, la présente invention concerne un système de culture ou de propagation de plante, des matériaux et un appareil destinés à être utilisés dans le système et des procédés utilisant le système. L'invention concerne un système de culture d'une plante, le système comprenant un matériau de propagation de plante et une capsule (10) pour faire croître le matériau de propagation de plante. La capsule comprend une coque (11); un couvercle (13) scellé sur la coque (11), définissant ainsi une cavité; un milieu de culture de plante (12) pour recevoir le matériau de propagation de plante, le milieu de culture de plante (12) étant contenu de manière fiable à l'intérieur de la cavité; et une ouverture pour racines formée ou pouvant être formée dans la coque (11), de telle sorte que, lors de l'utilisation du système, le matériau de propagation de plante produit des racines et au moins une racine de plante croît à travers l'ouverture pour racines. L'invention concerne également des capsules et des procédés de production de capsules, ainsi que des procédés de culture d'une plante.
PCT/EP2022/057558 2021-03-22 2022-03-22 Propagation de plante WO2022200391A1 (fr)

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US20150156973A1 (en) * 2012-02-17 2015-06-11 Oms Investments, Inc. Plant growing system and methods of using the same
US20170020095A1 (en) 2015-07-23 2017-01-26 Stephen Donald Kamholz Plant growing apparatus, systems and methods
WO2017156410A1 (fr) 2016-03-11 2017-09-14 Moleaer, Inc Compositions contenant des nanobulles dans un support liquide
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US20200045980A1 (en) 2018-03-20 2020-02-13 The United States Of America As Represented By The Secretary Of Agriculture Fungal volatile organic compound enhances plant s growth characteristics
EP3721979A1 (fr) 2017-12-08 2020-10-14 Takeshi Ohdaira Dispersion de nanobulles chargées, procédé de production de la dispersion de nanobulles chargées, dispositif de production de la dispersion de nanobulles chargées, et procédé d'utilisation de la dispersion de nanobulles chargées pour réguler la vitesse de croissance de micro-organismes et de plantes

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KR101954246B1 (ko) * 2018-08-30 2019-03-05 주식회사 에이아이플러스 IoT를 이용한 스마트 식물 재배기 및 스마트 식물 재배 시스템

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