Automatic watering systems for hydrating a cut tree or the like from a reservoir of standing water are described herein. Automatic watering systems may include a water source comprising a tank and a supply-water reservoir within the tank. Water may be automatically delivered from the supply-water reservoir to a tree-receiving reservoir which may be associated with a tree stand. Water in the tree-receiving reservoir may be taken up by the tree to keep the tree branches green and supple. A controller detects water levels in the supply-water reservoir and tree-receiving reservoir to control operation of a pump which pumps water to the tree-receiving reservoir for continuous tree hydration. The tank and other components of the system can be made to have the decorative appearance of a gift package to enhance the appearance of the tree and surrounding decor.

An assembly line grow pod includes a plurality of fluid lines fluidly coupled between a fluid source and a fluid destination within the assembly line grow pod, a plurality of valves, each coupled to a fluid line such that fluid movement through the fluid lines is selectively controlled by the valves, and a master controller communicatively coupled to the valves. The master controller is programmed to receive information relating to fluid delivery within the assembly line grow pod, determine one or more valves to direct the fluid, determine valve parameters for each of the valves that achieve the fluid direction, and transmit one or more control signals to the valves for directing the fluid within the assembly line grow pod.

A flexible greening system integrated with water into fertilizer includes a vegetation fixing assembly, a vegetation growth layer and a water supply assembly. The vegetation fixing assembly is configured to connect to a building. The vegetation growth layer is provided on the vegetation fixing assembly and is configured for planting of green vegetation. The vegetation growth layer includes a substrate layer for vegetation growth and a drainage layer provided below the substrate layer. The water supply assembly is configured to supply the water to the green vegetation, and is provided with a drainage pipe communicated with the drainage layer.

A container garden irrigation assembly includes a reservoir for containing a fluid. A pump is positioned inside the reservoir thereby facilitating the pump to be submerged in the fluid. A control unit provided that is in electrical communication with the pump. The control unit turns the pump on and off at predetermined times of day. A pair of irrigation units is each in fluid communication with the pump to receive the fluid from the pump. Each of the irrigation units has a plurality of irrigation ports therein and each of the irrigation units is positioned over a container garden. Moreover, each of the irrigation ports is aligned with a respective one of a plurality of containers in the container garden to release the fluid into the respective container.

A container unit for hydroponics includes a container having an overflow unit and an outflow unit located therein. The overflow unit includes an overflow tube, and the outflow unit includes a siphon pipe which is height adjustable. A cover is mounted to the container and includes an opening, a first hole and a second hole. A pot is engaged with the opening of the cover. Two hooks are connected to the back of the container so as to be hooked to a shelve to form multiple rows of the containers between which the overflow tubes and the outflow tubes are connected via the first and second holes of the containers. The overflow tube and siphon pipe control the water level in the container to prevent plant root from being rotted.

Disclosed herein are a planter apparatus and system. In one aspect, a planter system and apparatus can include one or more planting compartments, a water collection reservoir in fluid communication with at least one of the one or more planting compartments, and a water drainage system configured to drain water from one planting compartment into another planting compartment, drain water from one planting compartment into the water collection reservoir, or drain water from inside the water collection reservoir to outside the water collection reservoir, or a combination thereof. The planter apparatus may be further configured to include a water flow control component configured to: open for the flow of water through the water drainage system, and close, thus stopping the flow of water through the water drainage system based on the engagement and disengagement of a water drainage stopper mechanism at the base of the water drainage stopper. Also disclosed herein are methods of using the disclosed planter devices and systems.

A system for the fertigation of a plant vessel and method of use for the same is disclosed. The system comprises a grow module containing a plurality of growing trays additionally containing plants, and/or shoots of plants in various stages of development. The growing trays are individually extracted from the grow module via a tray movement system and tray elevator controlled by a control system and precisely placed in a fertigation system, wherein they are aligned over and lowered onto an at least one nozzle which penetrate the plant vessels containing the plants and fertigate them with a combination of water, nutrients, and/or pressurized air. The individual growing tray is then replaced in the grow module and the process is repeated for all growing trays and plant vessels in the grow module.

Horticulture devices, systems, and methods for growing vegetation are disclosed and described. The horticulture device can include a fluid reservoir operable to receive fluid therein to form a fluid column inside the fluid reservoir. The horticulture device can further include a fluid inlet formed in the fluid reservoir to allow fluid to be introduced into the fluid reservoir. The horticulture device can further include at least one vegetation receptacle in fluid communication with said fluid reservoir. The horticulture device can further include a drain positioned within the fluid reservoir having an opening corresponding to a maximum fluid level for the fluid reservoir.

A hydroponic cultivation apparatus, a system and a method for facilitating hydroponic cultivation is disclosed. The hydroponic cultivation apparatus includes a reservoir, a plinth, a grow tray with a grow tray lid, and a docking with coupler. The reservoir, placed upon the plinth, is located at a higher position adjacent to the grow tray for optimizing liquid circulation from the reservoir to the grow tray and vice-versa using one or more pipes, a solenoid valve and a pump. The base further includes a dock coupled to the grow tray for providing an electrical connectivity to the grow tray and simultaneously allowing the liquid to flow through the grow tray without being leaked. Further, the apparatus is having a roof which is provided with sources of illumination for providing light required for plant growth.

System and methods for monitoring the growth of an aquatic plant culture and detecting real-time characteristics associated with the aquatic plant culture aquatic plants. The systems and methods may include a control unit configured to perform an analysis of at least one image of an aquatic plant culture. The analysis may include processing at least one collected image to determine at least one physical characteristic or state of an aquatic plant culture. Distribution systems and methods described may track and control the distribution of an aquatic plant culture based on information received from various sources. System and methods described may include a bioreactor having a plurality of vertically stacked modules designed to contain the aquatic plants and a liquid growth medium.