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.

An agricultural implement includes at least one row unit having a plurality of support members, each of which is pivotably coupled to an attachment frame or another of the support members to permit vertical pivoting vertical movement of the support members, and a plurality of soil-engaging tools, each of which is coupled to at least one of the support members. A plurality of hydraulic cylinders are coupled to the support members for urging the support members downwardly toward the soil. A plurality of controllable pressure control valves are coupled to the hydraulic cylinders for controlling the pressure of hydraulic fluid supplied to the cylinders. A plurality of sensors produce electrical signals corresponding to predetermined conditions, and a controller is coupled to the sensor and the controllable pressure control valves. The controller receives the electrical signals from the sensors and produces control signals for controlling the pressure control valves.

Aspects of the present invention include a modular growing panel system for attaching vegetation to a surface of a structure. In one aspects, the modular growing panel system includes a growing substrate with a plurality of layers formed into a tile that is rigid and self-supportive of vegetation being grown in the growing substrate and a binder attaching one or more of the tiles to each other and forming the modular growing panel system. In another aspect, the modular growing panel system includes a growing substrate with a plurality of layers formed into a tile that is rigid and self-supportive of vegetation being grown in the growing substrate and a framework for holding and attaching one or more tiles to the structure created from a upper channel and having a slot that corresponds to the depth of the tile and a lower channel and having a slot corresponding to the depth of the tile. Yet another implementation of the modular growing panel system includes a growing substrate with a plurality of layers formed into a tile that is rigid and self-supportive of vegetation being grown in the growing substrate, a framework for holding and attaching one or more tiles to the structure created from a upper channel with an upper flange and having a slot that corresponds to the depth of the tile and a lower channel with a lower flange and having a slot corresponding to the depth of the tile; and upper molding to be affixed to the surface of the structure having a groove disposed to receive the upper flange of the upper channel of the framework and a lower molding to be affixed to the surface of the structure having groove disposed to receive the lower flange of the lower channel of the framework.

Various seed planter embodiments may comprise a frame including a main frame section and a furrowing disk frame section. A plurality of planter assemblies may be connected to the main frame section, and a plurality of furrowing disks may be connected to the furrowing disk frame section. At least one linkage may connect the main frame section and the furrowing disk frame section, and at least one motor may be configured to move the furrowing disk frame section with respect to the main frame section, wherein the at least one linkage permits the furrowing disk frame section to move to a low position for no-till planting and move to a high position for prepared seed beds or conventional planting.

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.

A system for obtaining water and carbon dioxide from an incoming first gas stream. The system comprises a first inlet for said incoming first gas stream, a first sorbent station comprising a first sorbent material for removing water vapour from said first gas stream, a second sorbent station comprising a second sorbent material for removing carbon dioxide from said first gas stream; and a first exhaust for said first gas stream. The system is configured to flow said first gas stream through the first inlet, the first sorbent station, the second sorbent station and the first exhaust. The system may be used in an environmentally controlled facility for growing plant material or in a building space conditioning. The present invention may therefore enable plant cultivation and/or building space conditioning whilst removing carbon dioxide from the atmosphere and therefore may help to combat climate change and benefit the environment, if implemented on a sufficient scale.

The present invention is a row cleaning device having a main body with a proximal end and a distal end, the main body proximal end is adapted to mount to a seeder. A pivot leg has a first end and a second end, the first end is pivotally mounted to the main body distal end at a pivot, the second end extends toward the main body proximal end. A clearing implement is mounted to the pivot leg second end and rotates with respect to the pivot leg. The row cleaning device is adapted to be driven by a seeder in a direction of travel with the clearing implement being located behind the pivot in the direction of travel. The pivot leg pivots with respect to the main body as the clearing implement moves along the ground in the direction of travel.

A vegetation wall system includes an irrigation tank, a vegetation mounting unit with a vegetation holding unit, a pump feeding water from the tank to the holding unit, a programmable logic control unit including a central processing unit and a sensor, wherein the central processing unit monitors an aspect in the wall system by measuring, by the sensor, a component of the aspect as a first component measurement, waiting a predetermined period of time and then measuring, by the sensor, the component of the aspect as a second component measurement, determining, by the central processing unit, a change in the aspect based on the first and second measurements and the predetermined period of time, determining whether the change is outside a threshold range, in response to determining that the change is outside the threshold range, determining that an anomalous condition exists, and generating an alert when the anomalous condition exists.

The present invention provides modified (e.g. genetically modified) plant cells and plants, the plants being characterised by an increase in any one or more of: bundle sheath cell numbers, bundle sheath volume, bundle sheath area, vein density, and/or the proportion of lateral veins, as compared to wild-type counterparts.

A Vertical-Hive Green Box (or V-Hive Green Box) is a modular cultivation system utilized in a modular Vertical Farm or Plant Factory, as well as a warehouse-type or greenhouse-type of vertical farm or plant factory. The V-Hive Green Box includes growing boards, lighting boards, and an irrigation system arranged within a frame structure to maximize the quantity of crops that can be grown within an available volume of space in a modular Vertical Farm unit, warehouse or greenhouse per unit time. The V-Hive Green Box can also include aquaculture boards that can be used for aquaculture of aquatic fish and plants.