A fixed irrigation landscape growing system comprises: a supporting substrate; a water absorbent blanket arranged above the substrate; and a growing medium, notably a soil layer, arranged above the water absorbent blanket. Irrigation is provided by irrigation pipes or by sprinklers.

The present invention concerns a geosynthetic element for a geotechnical engineering application. The geosynthetic element comprises: bacteria carriers for carrying bacteria arranged to be propagated from the geosynthetic element to a surrounding geomaterial; and a flow network comprising openings on its surface to allow a reactant to escape the flow network to the surrounding geomaterial along the flow network to produce solid calcium carbonate when in contact with the bacteria. The reactant flow network further comprises a set of inlets for feeding the reactant into the flow network, and a set of outlets for recovering at least a part of the reactant from the reactant flow network.

A multiple cell horticulture propagation tray arranged in rows of star-shaped cells forming a substantially rectangular shaped tray having the cells formed therein, combined with inserted cylindrically shaped growing media plugs comprising primarily of peat moss with an amount of biochar, and enveloped to retain moisture within the growing media plugs

The invention relates to a coherent growth substrate product formed of man-made vitreous fibres bonded with a cured binder composition and a wetting agent, wherein the wetting agent is an alkyl ether sulphate. The invention further relates to methods of using or producing such a coherent growth substrate.

The invention relates to a coherent growth substrate product formed of man-made vitreous fibres bonded with a cured binder composition and a wetting agent, wherein the wetting agent is an alkyl ether sulphate. The invention further relates to methods of using or producing such a coherent growth substrate.

A seedling nursery member for grafting according to an aspect of the present disclosure includes at least one seedling nursery unit. At least one seedling nursery unit includes a seed storage section configured to store a seed of a plant and have a space for the plant to germinate, a stem storage section configured to store a stem of the plant that has germinated and elongated, and a stem holder configured to hold the elongated stem of the plant. At least a portion of the seed storage section of at least one seedling nursery unit is configured to be openable to the outside of at least one seedling nursery unit. At least a portion of the stem storage section of at least one seedling nursery unit is configured to be openable to the outside of at least one seedling nursery unit.

A seedling nursery member for grafting according to an aspect of the present disclosure includes at least one seedling nursery unit. At least one seedling nursery unit includes a seed storage section configured to store a seed of a plant and have a space for the plant to germinate, a stem storage section configured to store a stem of the plant that has germinated and elongated, and a stem holder configured to hold the elongated stem of the plant. At least a portion of the seed storage section of at least one seedling nursery unit is configured to be openable to the outside of at least one seedling nursery unit. At least a portion of the stem storage section of at least one seedling nursery unit is configured to be openable to the outside of at least one seedling nursery unit.

A self-contained air filtration system is disclosed herein. The system includes a processor. The processor can receive data from one or several components of the system and can provide control signals to one or several components of the system. The system can include a housing. The housing can include: a reservoir portion; and a greenhouse portion. The greenhouse portion can connect to the reservoir portion via a grow tray. A top of the reservoir portion and the greenhouse portion define an enclosed volume. The greenhouse portion can include an inlet aperture and an outlet aperture. The inlet aperture can be obstructed by an inlet filter such that air flowing into the greenhouse portion passes through the inlet filter, and the greenhouse portion can be connected to a fan that can propel air through the inlet aperture and out of the outlet aperture.

A self-contained air filtration system is disclosed herein. The system includes a processor. The processor can receive data from one or several components of the system and can provide control signals to one or several components of the system. The system can include a housing. The housing can include: a reservoir portion; and a greenhouse portion. The greenhouse portion can connect to the reservoir portion via a grow tray. A top of the reservoir portion and the greenhouse portion define an enclosed volume. The greenhouse portion can include an inlet aperture and an outlet aperture. The inlet aperture can be obstructed by an inlet filter such that air flowing into the greenhouse portion passes through the inlet filter, and the greenhouse portion can be connected to a fan that can propel air through the inlet aperture and out of the outlet aperture.

Method for obtaining a growth medium for growing plants comprising taking organic waste suitable to the plants to be grown, mixing it to obtain a homogeneous material and reducing its microbial activity, incinerating organic waste suitable to the plants to be grown to obtain ash, a source of minerals suitable for the cultivation of said plants, and incubating the homogeneous material with the ash to restart the microbial activity, initiating the mineralization of the material, and obtaining a ready-to-use growth medium.