A modular multi-tiered planter kit that comprises two support elements that are fitted for positioning on a surface, perpendicular to the surface and spaced from each other, a plurality of planter assemblies that are fitted for connection in a disassemblable mounting, with the two support elements in a multi-tier configuration, wherein they each extend in an essentially horizontal direction, in the gap between the two support elements, wherein the kit is characterized in that once mounted as stated, the planter assemblies each comprise a unified planter element that serves in each of the planter assemblies, and the planter assemblies comprise one or more from the group of various types of planter assemblies.

Apparatus (2) for watering at least one plant (4), comprising: an outlet (6) for water (8) for the plant (4); water delivery means (10) which is operable between an on condition in which water (8) is delivered to the outlet (6), and on off condition in water (8) is not delivered to the outlet (6); a controller (12) for controlling the operation of the water delivery means (10); a timer (14) for controlling operation of the controller (12); a moisture sensor (16); user input means (18) which is configured for manual operation by a user to generate a plant-watering period, wherein the water delivery means (10), the controller (12) and the timer (14) are electrically operated; the user input means (18) operates consequent upon a first manual input by the user to cause the generation of a start time for the plant-watering period; the user input means (18) operates consequent upon a second manual input by the user to cause the generation of a stop time for the plant-watering period; the timer (14) operates to record the start time and the stop time, and causes the controller (12) to record the plant-watering period; the controller (12) operates the water delivery means (10) such that the water delivery means (10) starts subsequent to the first manual input and stops subsequent to the second manual input; and the moisture sensor (16) is operable to measure moisture in a growing medium in which the plant is growing.

An assembly well irrigation system for environmentally friendly water conservation includes: at least one well, having a ventilation tube inserted into the top of the well, an absorbent element covered onto the bottom and outer wall of the ventilation tube and filled up in an opening between the top of the well and the ventilation tube, and a float contained in the ventilation tube; and at least one water supply bottle, having a cover installed to the opening of the water supply bottle, and the cover having a fixed tube passing to the cover and a penetrating hole formed on the cover, and the penetrating hole having a movable tube capable of moving up and down for adjustment, and the water supply bottle being inverted, such that the cover is installed to the well, and the fixed tube, the movable tube and the ventilation tube are situated in the well.

The invention is a method and a system that use a distributed reservoir sub-system to maintain root temperatures in a modularized aeroponics setup. The reservoirs integrate with root chambers. Thermo-insulation materials and active temperature control functions are used to maintain temperatures of the nutrient reservoirs. Liquids in the reservoirs are further used as a media to maintain root chamber temperature and to reduce the fluctuations caused by pressurized nutrient delivery.

The invention relates to a plate-shaped structure for cultivating one or more plants. The plate-shaped structure may optionally collect moisture from the atmosphere and comprises a generally flat upper surface provided with a cavity for holding plant material. The cavity has a sidewall and a bottom portion. Further, the bottom portion includes an aperture traversing the plate-shaped structure. In use, the plate shaped structure can cover a reservoir or can be placed on the soil. The plate-shaped structure comprises a drain opening with a cap that is heavier than water and a covering cap so as to allow moisture to seep between the cap and the sidewall of the drain opening while minimizing evaporation.

The invention provides a plant growth system comprising growing substrates (110; 206; 306) as well as plants (P) of which the roots (R) grow in the growing substrate, a number of holding bodies (100; 202; 301) each having a bottom (101; 224; 324) and at least one bottom spacer (104, 105; 9b; 309b), the at least one bottom spacer at the upper side thereof supporting a growing substrate thereon such that a distance is maintained between the bottom and the growing substrate, irrigation means (331) for supplying water to the roots of the plants, drainage means having a drainage opening (241; 341) in the bottom as well as a common drainage which is in communication with each of the drainage openings for allowing water supplied by the irrigation means to the plants to drain via the drainage opening to the common drainage, a water permeable root barrier (123; 205; 305) for each holding body wherein the at least one root barrier is positioned below the upper side of the at least one bottom spacer, upstream of the common drainage for allowing passing of water throught the root barrier to the common drainage but preventing the roots from penetrating throught the root barrier in the common drainage.

A smart home gardening cabinet is disclosed that includes a plurality of plant growing drawers each having a vertical lift door and an automatic precision weather system to grow a specific type of plants, each automatic precision weather system includes an array of lights for photosynthesis, an air circulation system, and a water circulation system that provides nutrient water to the specific plants in each plant growing drawer; each plant growing drawers having a plant growing tray that includes an array of growing holes filled with a sponge materials to absorb and retain nutrients which are misted to the roots of the plants, excess nutrient water being returned to the water circulation system to save water.

A flexible water dispensing reservoir is provided. The device includes a flexible reservoir having a first end wall, a second end wall, and a plurality of sidewalls, defining an interior volume. A ventilation aperture and an inlet aperture are disposed through one of the plurality of sidewalls. A plurality of nozzles are disposed on one of the plurality of sidewalls. The ventilation aperture, the inlet aperture, and the plurality of nozzles are in fluid communication with the interior volume. A pump is disposed within the interior volume, wherein the pump is operably connected to the plurality of nozzles. When the pump is actuated, fluid disposed within the interior volume is dispensed through at least one of the plurality of nozzles. In some embodiments, a controller housing is in communication with the plurality of nozzles via a wireless transceiver, wherein the plurality of nozzles dispense fluid according to a programmed schedule.

An apparatus and method to regulate the fluid level in a plant watering device is described. In an embodiment, the plant watering device comprises a fluid reservoir that is supported by an adapter/fluid regulator that sits within a hollow permeable plant stake. The plant stake is designed to be pressed into soil adjacent to a plant growing in the soil. The adapter sits within the plant stake and acts as a valve with multiple settings that control the depth of water in the plant stake. Exposing the permeable plant stake to various levels of water affects the rate of permeation through the stake and thereby regulates the watering rate for the plant.

A planter water, oxygen and fertilizer measuring cup and soil penetrating tube apparatus is disclosed. The planter tube apparatus includes an upper reservoir and an angled lower dispensing tube. The upper reservoir includes a base and an upstanding wall, defining a volume, with a lower opening defined in at least one of the base and the upstanding wall in fluid communication with the volume. The angled lower dispensing tube extends from the upper reservoir. The angled lower dispensing tube is angled relative to the base of the upper reservoir. The angled lower dispensing tube has an outer surface and an inner channel, extending between a proximal end and a distal end, with a plurality of openings being positioned therebetween and extending through the outer surface and into the inner channel. A combination planter and planter tube apparatus is disclosed, as is a method of use.