A plant-growing apparatus having a first plurality of lighting panels coupled to a track within an aisle having vertical arrangements of botanical plants along both sides of the aisle. Each lighting panel hangs at fixed location on the track and is rotatable around a vertical axis relative to the track. Some embodiments simultaneously rotate all of the first plurality of lighting panels to alternately face one or the other side of the aisle. Each panel has a front face from which light is emitted. A first plurality of LEDs on the front face of each panel each emits a light spectrum that appears one or more of blue, red, white, infrared, and/or green. Some panels may be unlit at times. Some embodiments provide a continuously variable spacing between the lit face and the plants and variable scheduled lighting periods and changeable spectra for various types and growth stages of plants.

Some embodiments of the present disclosure provide a plant lamp. The plant lamp may include one or more light-emitting units and a lamp holder. Each of the one or more light-emitting units may include a light-emitting side and a non-light-emitting side oppositely disposed. The one or more light-emitting units may be mounted on the lamp holder. The plant lamp may further include one or more heat dissipation units located on the non-light-emitting side of at least one of the one or more light-emitting units, connected to the at least one light-emitting unit, and configured for heat dissipation of the at least one light-emitting unit.

A window for a greenhouse is provided that is comprised of a sheet of luminescent material [104] and light-energy converter [103]. The sheet comprises one or more luminescent materials [104] that absorb the peak wavelengths of the sun, emitting the absorbed photons to wavelengths primarily between 600 and 690 nm where they are converted to electrical power and/or enhance plant production. The luminescent material [104] is also transparent to a fraction of the wavelengths in the blue and red-portion of the solar spectrum which are required for plant growth and flowering. An additional polymer layer may be added as a luminescent layer, diffuser and/or IR reflector to further enhance plant growth and electricity generation.

A vertical farming layer structure comprising: an underlying support for supporting a plurality of farmed plants; a light-reflective upper surface positioned above and facing the underlying support, the light-reflective upper surface being adapted to reflect light by diffuse reflection; and a plurality of light-emitting devices positioned between the underlying support and the light-reflective upper surface, each light-emitting device being positioned to emit light along a respective optical axis oriented towards the light-reflective upper surface such that light emitted from the light-emitting device is at least partially diffusely reflected off of the light-reflective upper surface to reach the plants supported on the underlying support.

A plant factory includes a culture room, a lighting assembly, a CO.sub.2 concentration generation controlling module, an air conditioning module, a nutrient supplying module and a controlling module. The plant factory controls the lighting assembly to meet the lighting requirement of the different types of plants at each growth stage and the different types of plants at each growth stage are in the optimal growth state and grow in a predetermined manner of meeting the corresponding growth schemes. The plant factory improves planting efficiency and realizes lean production to achieve the zero inventory target meeting plant production characteristics.

A flexible datacenter includes a mobile container, a behind-the-meter power input system, a power distribution system, a datacenter control system, a plurality of computing systems, and a climate control system. The datacenter control system modulates power delivery to the plurality of computing systems based on unutilized behind-the-meter power availability or an operational directive. A method of dynamic power delivery to a flexible datacenter using unutilized behind-the-meter power includes monitoring unutilized behind-the-meter power availability, determining when a datacenter ramp-up condition is met, enabling behind-the-meter power delivery to one or more computing systems when the datacenter ramp-up condition is met, and directing the one or more computing systems to perform predetermined computational operations.

A light fixture includes a lighting module and a ballast. The ballast includes a housing and a power module. The housing includes a front cover and a rear cover. The front cover includes a front wall and upper fins and lower fins that extend from the front wall. The rear cover includes a rear wall and first fins and second fins that extend from the rear wall. The power module includes a plurality of heat generating semiconductor components that are thermally coupled with the rear wall to facilitate cooling thereof.

A method and apparatus for a horticultural light that projects either a substantially uniform target illuminance onto a flat surface or an increasing target illuminance onto a flat surface. The horticultural light uses a refractor to receive the raw light distribution from one or more LEDs and then distributes an optically varied distribution having a minimized intensity at centerbeam with an increasing beam intensity as the beam width increases. The horticultural light utilizes both ultraviolet (UV) LEDs and non-UV LEDs arranged as an array to produce the optically varied distribution. A lens array is disposed in relation to the LED array and is comprised of UV compatible lenses and non-UV compatible lenses. A device may be disposed in relation to the UV compatible lenses to disallow incidence of UV radiation onto non-UV compatible lenses.

An LED illumination system is operable to irradiate plant materials with photosynthetically active radiation. A lighting assembly includes a plurality of different LED types. Each LED lamp has a different spectral power matched to an absorption peak of the plant materials. All of the LED lamps of each different lamp type are driven by a different dedicated power source. Each power source can be independently modulated to vary the collective spectral power output of the LED illumination system. The lighting assembly includes fluid conduits disposed proximate to the LED lamps and a cooling fluid is flowed through the fluid conduits to removed thermal energy from the LED lamps.

Disclosures of the present invention describe a plant light raising and lowering apparatus. Particularly, a control module is configured for controlling a rope winch to complete at least one inching rotation along a clockwise direction or a counterclockwise direction, such that a base is driven by the rope winch so as to have an upward inching movement or a downward inching movement. Moreover, a counter is adopted for counting the direction, times and/or frequency of the inching rotation, and therefore the control module is able to know a total moving distance of the base by using the inching movement recording unit to record each time of the upward inching movement and each time of the downward inching movement. Therefore, a user is able to control the base to move back to a specific position such as an initial position or a previously-staying position.