A hydroponic system (1) is provided with a light-collecting apparatus (3) having a pair of reflecting plates (31a) that are vertically arranged in parallel with a culture surface (23) of a culture panel (21) of a hydroponic unit (2). During a process in which natural light taken from a light-collecting opening (30) propagates while repeatedly reflected by opposing reflecting surfaces of a reflecting plates (31a), by allowing seedlings p that are transplanted into the culture panel (21) to be irradiated with the light through a light-emitting hole (32) bored in the reflecting plate (31a), a culture object can be grown efficiently at a low cost by taking natural light from the outside.

An assembly for coupling to a downpipe of a building, including an elongate base support structure, said base support structure having a direction of extent that is coaxial the downpipe; and a series of receptacles coupled in spaced apart positions to the base support member in the direction of extent, wherein each receptacle of the series of receptacles is shaped to hold soil for growing plants therein.

Growing systems including double-walled growing devices, and methods of making and using the same are provided. Growing devices include two sheets of material, a sprouting layer and a rooting layer, strategically bonded together to form containers for growing plants. Each container includes openings in the layers to allow the plants to grow out of their containers and to allow roots to access water through the rooting layer. The two layers can be formed into a cylinder where the center of the cylinder provides a channel for watering such that the roots grow into that channel. Deployed as a flat sheet of containers, the device can include a third layer to provide a water channel between the rooting layer and the third layer. Growing systems include the device and can also include a system to provide water thereto, and an enclosure around the device for providing an overpressure.

A flower pot support assembly includes a rectangular panel defining a few windows. The support is engaged and retained into a corresponding panel window via lateral flange grooves. An arcuate seat is made integral to the panel window periphery and abuttingly cooperates with a corresponding flower pot support and associated window edge sloping ramps for flower pot support sliding and tilting engagement within the panel window, all in such a way as to releasably lock the flower pot support in nesting condition inside the panel window with the support member mouth facing upwardly.

The current invention relates to a plant growth and support module comprising (a) a backing (1), (b) a hydroponic substrate (8), wherein said hydroponic substrate (8) comprises an array of holes (9) for receiving a plant and/or a growth medium, (c) an irrigation layer, wherein said irrigation layer comprises a capillary material, and (d) a front (2), wherein said front (2) is connected to said backing (1), enclosing the hydroponic substrate (8) and the irrigation layer, said front (2) comprising an array of openings (4), said array of openings (4) are aligned with the holes of the hydroponic substrate (8), and wherein both the backing (1) and the front (2) comprise glass fibers, and which backing (1) and said front (2) are interconnected by means of an infusible stitching (3). Further aspects of the invention relate to a kit of at least two plant growth and support modules, a green wall, and a method of manufacturing a green wall.

Systems and methods for regulating growth of an organism. One aspect relates to a an environmental growth capsule which includes an intelligent skin infrastructure and growth capsules called biovoxels for the purposes of controlled variation of environmental parameters. Each biovoxel surrounds at least one growing biological material or organism, such as a plant or other biological organism and may contain appropriate growth media, such as soil, positioned in a hybrid plant product template. Further, in one aspect, at least one sensor monitors at least one environmental condition in each biovoxel and outputs sensed signals: and at least one actuator is actuated in response to actuation signals provided from a processor. The processor receives the sensed signals and outputs the actuation signals to change the at least one environmental condition. The capsule may be enabled with artificial intelligence.

The present disclosure generally relates to plant-based air purification systems and more particularly to wall mounted systems for removing impurities from indoor air using plants.

A tessellated ceramic apparatus for plant growth is set forth devised to support germination and plant growth upon an exterior surface. Water moves under osmotic pressure from a water storage volume disposed in osmotic communication with the ceramic, through the ceramic to become available water at the exterior surface. A graduated cross-section regulates water flow from a water storage volume through to the exterior surface along a pressure gradient exerted by the water head. Plant growth is facilitated within a plurality of tessellated indentations disposed upon the exterior surface and growth may be restricted from areas of the exterior surface by application of gloss, glaze, sealants and/or other surface features that may blend design elements to augment and support a living design.

A tower closing apparatus is provided that is configured to simplify the closing of a multi-piece, hinged hydroponic tower. The hydroponic tower closing apparatus utilizes a collection of static and continuously moving components (e.g., motor driven drive rollers, alignment rollers, tower body alignment rollers, face plate manipulation rollers, face closing rollers, etc.) to close a hydroponic tower as it passes through the apparatus. In particular, as the tower is driven through the closing apparatus, a series of face plate manipulation rollers gradually rotate the face plate(s) relative to the tower body, moving the face plate(s) from a fully open position to a partially closed position. Next a series of face closing rollers continue to rotate the face plate(s) from the partially closed position to the fully closed position, forcing the fasteners to latch the face plate(s) into position.

A plant-light system that includes a plurality of ducted plant-lighting plenum sheets, wherein each ducted plant-lighting plenum sheet includes a plurality of flexible perforated LED sheets, each LED sheet including a plurality of LEDs arranged on a grid, the plurality of LEDs including LEDs emitting light that appears red, light that appears blue, light that appears white, and light that is at least mostly infrared light, wherein each plant lighting sheet has a length and a width, and wherein the plurality of lighting sheets is arranged along a length of a room; a plurality of plant-holding pockets arranged along the length of the room generally parallel to the plurality of ducted plant-lighting plenum sheets; and a plant-lighting plenum sheets motion and withdrawal system arranged to move the plurality of ducted plant-lighting plenum sheets to a plurality of different locations relative to the plurality of plant-holding pockets for different time periods.