The system includes a pre-fabricated garden seedsheet, with seeds and soil embedded in water-soluble pods within a weed barrier fabric. Each water-soluble pod is fabricated from dissolvable material, which are affixed together to form cavities in which seeds and soil are applied. The pods are then affixed to the weed barrier matrix in an arrangement dictated by the plant algorithm. Upon contact with water, the pods rapidly dissolve, thereby beginning the germination process in which the seeds sprout and emerge through the aligned openings in the weed barrier fabric. The selection of plants and their physical arrangement within each seedsheet may be determined by a software-driven plant algorithm that extrapolates plant characteristics, environmental requirements, and companion benefits. The algorithm may be used both on the customer-facing software program, as well as the in-house design process to create pre-designed seed sheets.

A planter including a planter box and a rotatable mounting adapter that couples the planter box to a surface of an object. The adapter includes a first plate configured to directly couple to the planter box, a second plate configured to directly couple to the surface of the object, and one or more ball bearings between the first and second plates that allows the first plate and the planter box to rotate with respect to the second plate.

A device for cultivating plants is provided, comprising a watering device, an illuminating device, one or more seed mats, and a control unit configured to control the watering device and the illuminating device by means of a program controller, wherein the program controller comprises watering data and illuminating data which is individually matched to the one or more seed mats.

A device for cultivating plants is provided, comprising a watering device, an illuminating device, one or more seed mats, and a control unit configured to control the watering device and the illuminating device by means of a program controller, wherein the program controller comprises watering data and illuminating data which is individually matched to the one or more seed mats.

Floral architecture offers us technological solutions for convenient plant growing in pots, easy fitting into the given spaces with its size and design, modularity. A combination of components that create various systems are: pot with mats for plant growing (1), supporting structures (2), meshes (3), flexible water tank (4), water pump (5), time switch (7) or a computer (10), plug (8), irrigation system (9), door (11), filling hole (12), water purifier (13), system for tank filling (14), exterior masks or wall claddings (15), pergola (16), advertising space (17), seating area (18), lighting (19, 19.a), solar system (20), traffic signalling (21), water fountain (22), a storage box (23), drainage of excess water (24), fixer for pots (25), distribution box with a cover (26), drainage water hose (27), water supply hose (28), fence (29), distribution channel (30), divider (31), stretching system (32), flexible supporting structure for flower pots (33).

A plant air purifier with filter material within a filter bed container, wherein the filter material can both allow air to pass through it during the unit's air purification phase and for water to submerge the filter material during its remoisturization phase The unit itself passes through various phases and sub phases: an air purification phase; followed by a remoisturization phase, which includes an immersion of the filter material sub phase, and a draining away of the water during its drainage sub phase. And in some cases, a soaking sub phase of the filter material for some time. Three different embodiments of the unit are provided: a unit with a separate soaking; chamber outside the unit; one with an outer pot surrounding the filter container; and one with a flapper below the filter bed container.

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.

A planting container has a first basin and a second basin forming a yin-yang shape. The first basin is configured to contain soil, the second basin is configured to hold water and provided with a plastic floating board. The plastic floating board has a plurality of receiving holes with a planting basket. An inner side of the plastic floating board faces the first basin and has at least one opening allowing at least one fiber strip to pass through the opening and enter the second basin, and another end of the fiber strip passes behind the first and second basin and placed on or in the soil of the first basin.

A method and system for supporting containerized plants in an upright and stationary position and at customizable, uniform spacing therebetween. The system comprises a frame, pockets, stabilizers positioned within the pockets and spacers. The pockets, stabilizers and spacers provide both horizontal and vertical support to each containerized plant, holding it securely in place without stakes or cables. The pockets with stabilizers and the spacers may be arranged in various patterns to promote stability of the system and health of the containerized plants. An irrigation system may be coupled to the system for maintaining and nourishing plants. The length of the frame is greater than the width, thus creating a stable environment to combat winds and disruptive forces. Individual frames may be attached to form designated and defined uniform growing or display areas and provide greater stability.

The present invention relates to a device and method for sowing seeds. The invention relates more particularly to a device and method for sowing seeds as part of a plant. The system according to the invention comprises a separating device for separating a single seed relative to a remainder of the plurality of seeds, an optical recognition system (9) for recognizing the separated seed, a robot arm device (4) for picking up the separated seed and for sowing the picked-up seed, arid a control unit for controlling the separating device, the optical recognition system (9) and the robot arm device (4). With this system it is possible to sow seeds in a more accurate and less error-prone manner.