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, the grow module defining a plurality of grow chambers spaced apart along the circumferential direction. One or more resilient sealing elements, e.g., formed from silicone, are positioned at the distal ends of the grow module to seal a gap between the grow module and the liner. The resilient sealing elements define one or more air ducts for providing a flow of air through the resilient sealing element into one of the plurality of chambers and a flow regulating device for regulating the flow of air.

A lighting device and assembly which incorporating an independently powered array of at least two types of LED lights that each give off specific wavelengths of light for growing plants. The assembly includes at least two of the lighting devices in conjunction with at least one high intensity bulb commonly used for indoor horticulture, where the assembly is adjustable for dimensional changes in the subject plants as they grow. A timing method for applying specific durations of each type of light which effectively simulate sunrise, daylight and sunset by allowing the plant to awaken naturally, absorb more light during the day and prepare for sleep at night, giving the plant more rest—all leading to more healthy plant growth.

An apparatus is provided. There is a substantially rectangular frame having a plurality of corners with a light panel that is secured to the frame. Brackets a first opening are secured to each corner. Mounting members are secured to the brackets. The mounting members have: a first body; a second and third aligned openings formed in the first body; a fourth opening formed in the first body; and a plurality of second bodies, where each second body extends from the bottom face of the first body. Also, each second body includes a front and a rear, wherein the front of each second body is at least partially set back from the front face of the first body, and wherein the rear of each second body is substantially aligned with the rear face of the first body.

A method for operating a greenhouse system with block storage, at least one block storage element and at least one vehicle. Growth conditions for plants are to be improved. To this end, each block storage element has a carrier frame and a plant receptacle, the plant receptacle being detachably engaged with the carrier frame, the block storage having at least one first zone and one second zone, and at least one first carrier frame and at least one second carrier frame, the plant receptacle in the first zone being detachably engaged with the first carrier frame; and the plant receptacle being subsequently transferred into the second zone, the plant receptacle being transferred from the first carrier frame to the second carrier frame within the framework of transferal from the first zone into the second zone, the plant receptacle in the second zone being detachably engaged with the second carrier frame.

A plant growing apparatus irradiates plants by switching white light from a white light source into light of a color of a specific wavelength by using a partition plate that partitions a light source placement space and a plant growing space. The plant growing apparatus includes: a white light source emitting white light and being provided to face plants to be grown; a light source placement space to place the white light source; and a plant growing space to place the plants to be grown; a housing facility blocking entry of external light; and a partition plate that extends in the housing facility in a horizontal direction, and includes a filter blocking at least one of temperature transfer and air circulation between the light source placement space and the plant growing space, and transmitting light of a specific wavelength in the white light from the white light source.

Three-dimensional vegetation growing systems provide an enclosed hydroponic environment for growing plants. The system serves to uniformly expose the plants to nutrients, liquids, and light from multiple directions while the plant rotates. In some embodiments, the three-dimensional vegetation growing systems may include a system housing configured to form an enclosed hydroponic growing environment; at least one light source in the system housing, the at least one light source configured to emit light; a distribution portion in the system housing, the distribution portion configured to discharge a vegetation growth sustaining liquid; and at least one conveyor device in the system housing, the at least one conveyor device disposed in proximity to the distribution portion, the at least one conveyor device configured to support vegetation and rotate the vegetation in the system housing as the vegetation receives the vegetation growth sustaining liquid from the distribution portion and the light from the at least one light source. Other embodiments of the three-dimensional vegetation growing systems are also disclosed.

A light fixture for an indoor grow facility is provided. The light fixture includes a plurality of LED lights, a controller, a digital communication module, and an analog communication module. The controller is in signal communication with the plurality of LED lights. The digital communication module receives a digital control signal. The analog communication module receives an analog control signal simultaneously with the digital control signal. The controller is configured to select between either the digital control signal or the analog control signal for controlling the plurality of LED lights.

A fodder growing apparatus includes an insulated housing having a draining floor, a door-closable open face, and a plurality of vertically-spaced platforms being supported in a position inclined downward between 3° and about 6°. The apparatus further includes pass-through irrigation system including spray nozzles supported over each of the platforms and supplied with water. An illumination system of the apparatus includes an LED equipped lighting assembly supported over each of the platforms. A ventilation system of the apparatus includes forced ventilation means. The apparatus further includes a programmable controller selected to deliver a time-variant program of at least irrigation and lighting, and temperature control means controlling the temperature within the housing.

The invention relates to a container for containing a living organism, a docking station for docking the container, and a transportation system comprising the container and the docking station. The container comprises a docking for docking the container to a docking station. The docking station comprises a light emitter. The container comprises light-guiding means for guiding at least part of the light emitted by the light emitter to the living organism. The effect of the measures according to the invention is that the light required for illuminating the living organism is generated by the light emitter of the docking station. As a result, no light emitters are necessary in the container according to the invention which reduces the cost of the container.

A grow light for stimulating plant growth is presented herein. The grow light includes a plurality of primary light modules with LEDs fixedly mounted to a support assembly and spaced a distance away from a plant canopy, and one or more secondary light modules movably or pivotally mounted to an end of one or more of the primary light modules. A positioning assembly is disposed interconnected light modules for manually or automatically movably disposing the secondary light modules into different angular positions relative to the plant. A height adjustment assembly is also include to movably position the light assembly, such as the plurality of primary light modules or the secondary light modules in a vertical direction. Additional features can be included, such as positioning sensors, environmental sensors, CO2 delivery systems, water cooling systems, ground wire interconnections, and light frequency control.