A plant grower includes a base, an upper cover having a surface parallel to an upper surface of the base, the upper cover being disposed above the base so as to be spaced apart from the upper surface of the base, a plurality of growing panels disposed along the circumference of the upper surface of the base, the plurality of growing panels being rotatably disposed at the base and the upper cover, and a lighting bar extending vertically upwards from the center of the upper surface of the base to the upper cover, the lighting bar emitting light in a direction in which the plurality of growing panels is disposed, and a plurality of growing holders, into each of which a plant is inserted, disposed at one surface of each of the plurality of growing panels.

Disclosed are a system and method for managing a smart farm using a self-contained hydrogen power system. A system for managing a smart farm includes a self-contained hydrogen generation unit configured to purify intake-water, generate clean hydrogen through water electrolysis, generate energy through a fuel cell by using the generated clean hydrogen, and store the energy; and a growing condition control unit configured to receive, from the self-contained hydrogen generation unit, energy for driving a plurality of sensors and a camera and control an environment for growing agricultural produce.

A system for lighting a plant comprising a dome/cage defining a volume that receives, surrounds and covers the plant. A plurality of light sources are supported by the dome/cage and distributed vertically from a bottom to a top and around the dome/cage to illuminate the plant evenly. The system is adapted to control the light sources to project light in the dark, extend ambient light hours, increase an intensity of an existing light; and modify a spectrum of the existing light in accordance with growth requirements specific to a given plant growing in a specific environment. A solar panel may be connected to the lights directly or through a battery for operating the system as a standalone unit. A control unit may be provided to receive a user input setting a lighting program, to allow the system to control operation of the lights using the set program.

An array system of passive solar aquaponic and mushroom production structures, each having a glazing on a sun facing side to maximize winter sunlight; a plant growing area; a mushroom growing area; a water wall thermal mass integrated and disposed between the plant and mushroom growing areas; a fish tank; a saltwater basin under the plant growing holding saltwater; a natural air ventilation system providing misted air to the mushroom growing area and receiving O2 from the plant growing provided to the mushroom growing area, and CO2 generated by the mushroom growing area provided to the plant growing area; and saltwater channels delivering saltwater to the saltwater basins from a saltwater source, and which is evaporated by solar heat generated by the plant growing areas in order to generate freshwater.

A solar module assembly includes a frame having an upper portion encompassing an area and a mid portion disposed below the upper portion. A plurality of solar panels is arranged in a string, sandwiched between two transparent panes forming a single string panel. The solar panels occupy less than the area of the upper portion. Each of the plurality of solar panels has a pair of opposing edges. A reflector is mounted on the mid portion to reflect light selectively.

A modular gardening system (MGS) for plant growing, the system comprising a garden bed for containing soil that is configured to grow at least one plant therein; an elevated rolling stand module supporting the garden bed; a bed cover system module disposed on top of the garden bed; and a mister irrigation module providing irrigation to the plant.

A strut and method using same is provided. The strut comprises a body member having a longitudinal axis, a first end and a second end. A first gripping member is connected to the first end of the body member. The first gripping member comprises a first plate for engaging a first structural engagement member. A second gripping member is connected to the second end of the body member. The second gripping member comprises a second plate for engaging a second structural member. The body member of the strut extends in a direction to intercept each of the first and second plates.

Disclosed is a smart farm system comprising: a Rankine cycle in which a first fluid passes through a pump, an evaporator, a turbine, and a condenser along a first circulation line; a heating unit configured to exchange heat with the evaporator; a valve unit which is provided between the turbine and the condenser, and configured to run the first fluid to the condenser when the temperature of the first fluid at the outlet of the turbine is a first temperature, and to bypass the first fluid to a bypass line when the temperature of the first fluid at the outlet of the turbine is a second temperature higher than the first temperature; and a smart farm configured to exchange heat with the first fluid and the heating unit via the condenser or the bypass line.

The power barn system provides a way to eliminate greenhouse gas (GHG) emissions from livestock. The power barn system seals and traps the methane gas that is emitted from the livestock and converts the methane into electric power and carbon dioxide to enhance plant growth. The power barn system uses PV solar arrays and plastic sheeting to make sealed, airtight structure. The carbon dioxide is provided to greenhouse areas. The plants use the carbon dioxide and release oxygen, thereby eliminating most greenhouse gas emissions from livestock. The power plant uses the methane at peak times at night while solar panels supply power during the day producing zero emission meat and 24/7 electricity at better than market rates.

A solar tracker system is a system and method to integrate the solar cells to a greenhouse. The solar tracker system comprises solar tracker modules that include solar cells, racks, gears, pinons, motors, and mounting brackets to efficiently and conveniently be installed to the roofs and walls of a new greenhouse and/or an existing greenhouse for retrofit application. Additionally, the solar tracker system uses various sensors to provide real-time conditions to the greenhouse. The method uses actual or system default values to adjust the angle and position of solar cells according to various environmental factors, such as DLI, weather, date, time, direction of sunlight, or type of plant.