An indoor gardening appliance includes a liner defining a grow chamber and a grow module rotatably mounted within the grow chamber for receiving a plurality of plant pods. A moisture management system includes an evaporator plenum in fluid communication with the grow chamber and a fan assembly that recirculates air from the respective grow chambers and/or the ambient environment through an evaporator positioned within the evaporator plenum. In this manner, chamber humidity may be regulated while water is extracted from the air which may be used by a hydration system to hydrate plants.

Hydroponics systems and methods of efficient, configurable nutrient solution grow reservoirs include shared components while creating more space in grow facilities. The hydroponics systems include vertical and horizontal rows or layouts of connected reservoirs that may include movable reservoirs to allow for better user access and reduce aisles, which allows space for more reservoirs in a grow facility. Multiple reservoirs may be connected to one another by irrigation tubing (e.g., as shown in in vertical layouts) or by pipes or irrigation tubing (e.g., as shown in horizontal layouts) and share various multiple system components, such as water pumps, water chillers, air pumps, float valves, and drain out systems. In some implementations, incorporation of the 4″ pipes in the horizontal layouts provides for efficient water circulation in a closed loop configuration throughout the disclosed hydroponic systems.

A plant cultivation device and a greening apparatus thereof are provided. The plant cultivation device includes a fixing member which includes a first channel, a shared channel and a plurality of first through-holes. The first through-hole is connected with the first channel and the shared channel, and passes through an upper surface of the fixing member. Both the first through-hole and the shared channel are stack-up with each other, and the first through-hole is located above the shared channel. The shared channel is configured to fill with a cultivation medium,and the first channel is configured to store water flowing from the shared channel by the first through-hole when too much water is stored in the shared channel. The present disclosure can optimize a growing environment of plants.

Embodiments of the disclosed technology are directed to devices and/or apparatuses for receiving, housing and displaying plants on surfaces having a repetitive pattern of elevation changes resulting in multiple horizontal planar surfaces of varying elevation. The apparatus may be, for example, a caddy adapted to conform to the staggered pattern of one or more steps, curbs, ledges, and/or walls. The caddy may be further adapted to receive and store, at an angle between 0 degrees and 90 degrees, an elongated planter. In further embodiments, a self-contained planter may be disclosed. The planter may be adapted for receiving soil, planting substrate and/or plants. The self-contained planter may have a base region adapted to conform to the staggered pattern of one or more stepped surfaces.

A green roof planter module includes a planter including a bottom wall and a plurality of side walls that cooperate with one another to define an interior space configured to receive an aggregate and plant matter therein, the bottom wall including at least one aperture extending therethrough, a basin including a bottom wall and a plurality of side walls, wherein the bottom wall of the basin and the side walls of the basin cooperate to define a fluid retention space, wherein the planter is supported above the basin, and a fluid wicking member providing fluid communication from the fluid retention space of the basin to the at least one aperture of the bottom wall of the planter, such that the fluid wicking member is configured to transfer fluid from the fluid retention space of the basin to the aggregate and plant matter located with the interior space of the planter.

An aquatic weed planting plate for an aquarium is provided. The aquatic weed planting plate for aquarium includes a plate body and at least four feet. A plurality of planting holes is formed in the plate body at intervals. A plurality of dirt collecting holes is formed around each planting hole. The plate body is provided with fixing devices for fixing aquatic weeds, and each fixing device corresponds to one planting hole. The fixing device includes a fixing sleeve, two clamping members and a luminous ring. The plate body is provided with nets for collecting dirt, each net corresponds to one dirt collecting hole, the lower portion of each net is provided with a connecting tube; a plurality of conveying pipes is also arranged below the plate body, each conveying pipe is communicated with the plurality of connecting tubes, each connecting tube is communicated with the corresponding conveying pipe.

A raised garden box assembly. The raised garden box assembly may include a plurality of hollow sidewalls, each hollow sidewall may have a top rail, a bottom rail, an inner side member and an outer side member, where the top rail is connected to an outer side member and an inner side member and the bottom rail is also connected to the inner side member and the outer side member. The outer side member and the inner side member may form a hollow interior space and each of the plurality of hollow sidewalls may include a plurality of support ribs, each of the plurality of support ribs may directly contact the outer side member and the inner side member. The top rail, bottom rail, outer side member, inner side member and plurality of support ribs of each hollow sidewall may be integrally formed as a single unitary piece via an extrusion process. The raised garden box assembly may also include a plurality of hollow corner posts, each corner post having a first and second opening, where each of the first and second openings may receive a terminating end of one of the plurality of hollow sidewalls, the plurality of hollow sidewalls and corner posts forming an enclosure.

A seedling raising device includes: a cell plug for seedling raising that is formed as a single pot body; and a supporting device configured to detachably arrange and support a plurality of cell plugs, wherein the supporting device is capable of supporting the cell plug in either one of a first supporting position where the cell plug is slidably supported in a horizontal direction and a second supporting position where the cell plug is detachably supported in a top position.

A method of increasing interspace among plant containers. The method comprises: providing a set of plant containers, the set comprising first and second plant containers; arranging the first plant containers in a first structured grid formation along a horizontal plane; and arranging the second plant containers in a second structured grid formation along said horizontal plane, whereby when viewed from above the first and second plant containers are alternatingly arranged in a joint structured grid formation in a first area. The method comprises, for increasing the interspace among the plant containers, mutually simultaneously moving the second plant containers in their second grid formation away from the first plant containers in a vertical direction and subsequently placing the second plant containers in a second area.

A cultivar growing system is disclosed that may comprise a plurality of chambers. Each chamber comprises a floor, walls and a ceiling. The chambers also support a plurality of cultivars. The chambers also include sensors that monitor light, temperature, humidity, leaf temperature, vapor pressure deficit, carbon dioxide, plus grow medium temperature, oxygen, pH level, total dissolved solids, and electrical conductivity, and nutrients in the chamber and lighting elements that supply light from the direction of the ceiling of the chamber. The chamber also includes an air supply that supplies air from the direction of the floor of the chamber and a nutrient supply that provides nutrients and water to the cultivars. The chamber may also include one or more control systems for controlling the lighting elements, air supply and nutrient supply, wherein the one or more control systems incorporates information from the sensors and a predetermined growth recipe.