A latchably closable horticultural capsule is configured to contain a growing medium, and to be temporarily closed around a branch section of a parent plant during an air-layering propagation process. The capsule includes a first shell portion and a second shell portion pivotally joined together by a central hinge. The first shell portion includes a main shell body having a cup-like shape configured to partially surround the branch section, the main shell body having opposed end walls with notches formed therein. The first shell portion also includes two seal-receiving cups externally attached to the end walls of the main shell body. The seal-receiving cups have hollow notches formed in respective edge portions thereof, and are also configured to partially surround the branch section. The notches of the seal-receiving cups are substantially linearly aligned with one another, and also with the notches of the main shell body.

A semi-automated crop production system featuring a growing module with grids of cells for growing plants and a lighting and airflow fixture positioned above each cell. The lighting and airflow fixtures feature a fan disposed in a housing, a light emitting diode (LED) assembly board comprising LEDs disposed below the fan; a light diffuser disposed below the LED assembly board, and an adjustable airflow nozzle extending downwardly from the fan and protruding through the LED assembly board and the light diffuser. The adjustable airflow nozzle provides directed airflow downwardly toward a bottom area of the housing. The growing module and lighting and airflow fixtures are housed in a shell. The growing module may be slidably attached to the interior wall of the shell via mounting components.

A system and method are provided for indoor agriculture using at least one growth chamber illuminated by laser light. In an example embodiment of the agriculture system, a growth chamber is provided having one or more walls defining an interior portion of the growth chamber. The agriculture system may include a removable tray disposed within the interior portion of the growth chamber. The agriculture system also includes a light source, which may be disposed outside the growth chamber. The one or more walls may include at least one aperture. The light source is configured to illuminate at least a part of the interior portion of the growth chamber. In embodiments in which the light source is disposed outside the growth chamber, the light source is configured to transmit the laser light to the interior portion of the growth chamber via the at least one aperture.

A system and method are provided for indoor agriculture using at least one growth chamber illuminated by laser light. In an example embodiment of the agriculture system, a growth chamber is provided having one or more walls defining an interior portion of the growth chamber. The agriculture system may include a removable tray disposed within the interior portion of the growth chamber. The agriculture system also includes a light source, which may be disposed outside the growth chamber. The one or more walls may include at least one aperture. The light source is configured to illuminate at least a part of the interior portion of the growth chamber. In embodiments in which the light source is disposed outside the growth chamber, the light source is configured to transmit the laser light to the interior portion of the growth chamber via the at least one aperture.

A horticultural container includes a tag slot for receiving a display tag. The tag slot has an inner wall and an outer wall spaced widthwise from one another, and one of the inner or outer walls has at least two curved peaks separated by a valley and extending into the slot towards the other of the inner or outer wall to hold the tag against the other of the inner or outer wall. The peaks provide a radius that reduces cracking of the tag and increases longevity thereof, and reduces tag sagging, collapsing, or curling.

An apparatus for growing plants is includes a body section having an upper orifice, a lower orifice, a back section, and at least one door. The upper orifice allows for planting of a plant while the at least one door allows for removal of the plant for transplanting. The upper orifice is smaller in cross-sectional area than the lower orifice allowing for plants to grow in their natural pattern giving the roots more room to grow in more soil from which to absorb nutrients making for a happier, healthier plant which will not need to be transplanted as often.

A mixed media farm may include a tray for holding water at a prescribed water level. A cell may be placable on the tray, with the cell defining a cavity and having at least one opening in communication with the cavity. The cell may be sized such that when the cell is placed on the tray, a lower portion of the cell resides below the prescribed water level and an upper portion of the cell resides above the prescribed water level. Soil may be in the cavity, with the soil having a lower portion below the prescribed water level, and an upper portion above the prescribed water level when the cell is placed in the tray. A plurality of seeds may be planted in the upper portion of the soil, with the plurality of seeds defining a seed density of greater than 5 seeds per square inch.

Disclosed is a system having a base and a screened enclosure for disposition on the ground for growing plants. The base forms a hollow enclosure into which a growing medium can be disposed. The screened enclosure is mounted on the base and is in the form of a plurality of elongated frame members, plural upper screen members and plural lower screen members. Each of the screen members has an opposed pair of side edges, a top edge and a bottom edge. The frame members extend upward from the base and are spaced apart from one another. Each of the frame members includes a first respective section arranged to slidably receive a respective side of a respective lower screen member therein and a second respective section arranged to slidably receive a respective side of a respective upper screen member therein. Each of the upper and lower screen members are arranged to be individually removed from their respective sections of their associated frame members to enable each of the screen members to be individually removed from the frame members.

The disclosure relates to a plant growth apparatus and related system to grow and maintain plants under controlled biotic conditions, for example to grow axenic (microbe-free) plants, gnotobiotic (defined microbiota) plants, and holoxenic (complex, or undefined microbiota) plants. This system allows aseptic bottom irrigation with water, soluble nutrients, chemicals, and/or microbiota. Plants can be inverted for dipping and/or vacuum infiltration. The system also allows for passive (gravity) drainage, thereby allowing for gas exchange and preventing root anoxia. A variety of plant growth substrates can be used within the plant growth apparatus as a plant growth medium. The plant growth apparatus, containing the growth substrate medium, can be completely flushed via the drainage port to remove potential toxic byproducts of the sterilization processes. The entire system is suitably constructed using autoclavable material.

A novel collapsible plant support includes a collapsible coil adapted to rest on a flat surface. In a particular embodiment, the collapsible plant support includes a plurality of vertical support structures coupled to the collapsible coil so as to provide additional support. In another particular embodiment, a collapsible plant support includes plant receptacle receiving element that supports both a collapsible coil and also a plant receptacle. In a more particular embodiment, the plant receptacle receiving element includes fluid ducts for connecting multiple plant receptacle receiving elements into a fluid network. In another embodiment, the coil is disposed within a helical sleeve coupled to a flexible, cylindrical mesh.