A modular greenhouse assembly may include one or more grow containers, each having a plant space, and one or more support containers. The containers may be positioned side by side and stacked on top of each other. By properly, but easily, aligning corresponding ports in the containers, light and air can be conveyed to properly care for the plants in the plant space.

A modular greenhouse assembly may include one or more grow containers, each having a plant space, and one or more support containers. The containers may be positioned side by side and stacked on top of each other. By properly, but easily, aligning corresponding ports in the containers, light and air can be conveyed to properly care for the plants in the plant space.

A terrarium including a base, a support column, a top, and one or more panels with a closure is provided. The base can include a base channel, and the top can include a top channel. The top can be supported by the support column above the base. A panel can extend between the top and the base, being disposed in the top channel and the base channel, and forming an opening. Another panel can form a closure over the opening, with that panel optionally slidable to selectively access an internal compartment of the terrarium. A floater projection can be included on the closure panel and can engage a support rim on the base channel so as to support the panel and reduce friction of the panel moving relative to the base channel, for example, by supporting the panel above a channel bottom wall. Related methods of use are provided.

The invention relates to an easy-to-use system that provides an all-in-one shipping container farm that enables a user to grow 4,400-12,000 plants per month and provides the infrastructure to raise the plants from seed to harvest. The system provides an integrated system which provides nutrients, water, light and controlled atmosphere to raise the crops.

A greenhouse comprises a support frame and a spray pipe including pipes and pipe joints, the pipe joint comprises a connecting pipe and two rotary sleeves, the two adjacent pipes are respectively inserted into the connecting pipe, ends of a first pipe are respectively sleeved with a sealing sleeve and a locking sleeve, and each of the ends of the first pipe is further sleeved with a washer. When the rotary sleeve is thread-tightened, the connecting pipe and the locking sleeve are capable of respectively abutting and pressing against two sides of the washer, under abutting and pushing of the rotary sleeve and limiting of the washer, the locking sleeve is capable of grasping the first pipe and forming an axial positioning with the rotary sleeve. An inner edge of an end surface of the connecting pipe has a sealing tapered surface capable of acting on the sealing sleeve.

A growing device (mini-greenhouse) comprising a dome for growing crops therein and a light module operably installed on an exterior of the dome for projecting a light beam onto the crops. The dome comprises one or more openings/cutouts therein poisoned at locations that match the locations of corresponding lights of the light module such that the path of the light beam is unobstructed by the material of the dome. The light module is configured to dissipate the heat generated by the lights away from the dome, whereby the base portion of the light which includes the necessary circuitry is contained within the light module and the light beam projected in the dome is either reflected by a protruding reflector that penetrates the dome or a flat reflector that projects the light through the opening. The light module may include vents and/or fans for dissipating the heat into the atmosphere.

A growing device (mini-greenhouse) comprising a dome for growing crops therein and a light module operably installed on an exterior of the dome for projecting a light beam onto the crops. The dome comprises one or more openings/cutouts therein poisoned at locations that match the locations of corresponding lights of the light module such that the path of the light beam is unobstructed by the material of the dome. The light module is configured to dissipate the heat generated by the lights away from the dome, whereby the base portion of the light which includes the necessary circuitry is contained within the light module and the light beam projected in the dome is either reflected by a protruding reflector that penetrates the dome or a flat reflector that projects the light through the opening. The light module may include vents and/or fans for dissipating the heat into the atmosphere.

A plant cultivating apparatus according to an embodiment of the present disclosure includes a main body, a shelf, a cultivation bed, and a cultivation container. The shelf is disposed in the cultivation space formed in the main body, the cultivation bed is disposed on the shelf, and the cultivation container is seated in the cultivation bed. The cultivation bed includes a water supply part for receiving a predetermined amount of water. In addition, the shelf includes a water level sensor. The water level sensor is positioned vertically below the water supply part to measure an amount of water stored in the water supply part.

A container for growing plants includes a bottom wall, a first side wall extending perpendicular to the bottom wall, and a second side wall extending perpendicular to the bottom wall and parallel to the first side wall such that the bottom wall, the first side wall, and the second side wall at least partially define a plant growing chamber. Furthermore, the container includes a lid configured to selectively occlude access to the plant growing chamber. Additionally, one of the bottom wall, the first or second side walls, or the lid includes a rail and another of the bottom wall, the first or second side walls, or the lid defines a groove such that the rail of the container is configured to be received within a groove of a first adjacent container and the groove of the container is configured to receive a rail of a second adjacent container.