A vivaria assembly for separating aquatic animals and plants from terrestrial animals and plants includes a container and a set of panels. The panels are engaged to the container and positioned in an interior space defined by the container. Each panel extends from a bottom to proximate to a top of the container so that the container and the panels define a plurality of compartments within the interior space. The panels and at least a portion of a wall of the container are substantially transparent. A plurality of cutouts is positioned in the container so that each compartment has at least one cutout permitting access to the compartment. A respective habitat element and at least one of an animal and a plant can be inserted into each compartment to create a respective vivarium within the compartment.

A foldable aquaponics, and greenhouse container system and method, includes an insulated shipping container having foldable insulated roof panel disposed thereover; a foldable glazing on a sun facing side at an angle to maximize winter sunlight attached to the roof panel; a foldable floor panel attached to the container with a foldable vent panel attached thereto connecting to the glazing; foldable side panels attached to sides of the container, glazing and roof panel; a plant growing under the glazing; a mushroom growing area within the container having an integrated water wall thermal mass and disposed between the plant and mushroom growing areas; a fish tank within the container; and a natural air ventilation system within the container under the roof panel to provide CO2 and O2 gas exchange between the mushroom growing area and the plant growing area.

An aquaculture system including a fish holding unit which is fluidly connected to a water recirculation conduit, a water treatment unit, a water inlet, and a feed storage unit. The system further includes a feed loading section. When feed is added into the system at the feed loading section it is transported to the fish holding unit. In another aspect the invention relates to a method of transporting a feed in a recirculated aquaculture system.

A light-emitting device includes a light emitter including a light-emitting portion that emits first emission light having a first peak wavelength in a range of 380 to 425 nm and a half width of 15 to 35 nm, and a coating located over the light-emitting portion of the light emitter and containing phosphors to emit second emission light having a second peak wavelength in a range of 430 to 475 nm and having a third peak wavelength in a range of 490 to 540 nm. The light-emitting device emits external emission light having a peak region including the first peak wavelength, the second peak wavelength, and the third peak wavelength 14P02303 and having a long wavelength region defined between an upper end of the range of the third peak wavelength and a wavelength of 750 nm in which a light intensity decreases continuously.

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.

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.

The present invention relates generally to agricultural growing apparatuses and methods. More specifically the present invention relates to a dynamic, modular, rotating apparatus, and methods related to the apparatus' use and/or function.

The invention provides a light generating system for arthropod keeping, configured to generate system light, wherein in a first operational mode the light generating system is configured to provide the system light having a spectral power distribution, wherein the spectral power distribution comprises: a first spectral power E.sub.1 in a first wavelength range of 360-780 nm; a second spectral power E.sub.2 in a second wavelength range of 360-400 nm; a third spectral power E.sub.S in a third wavelength range of 400-480 nm; a fourth spectral power E.sub.M in a fourth wavelength range of 480-580 nm; a fifth spectral power E.sub.L in a fifth wavelength range of 580-700 nm; a sixth spectral power E.sub.6 in a sixth wavelength range of 620-700 nm; a seventh spectral power E.sub.7 in a seventh wavelength range of 700-780 nm; and wherein: 1.75≤E.sub.M/E.sub.S≤20; E.sub.2/E.sub.1≤0.005; E.sub.7/E.sub.1≤0.022; and E.sub.L/E.sub.1≤0.3; or 0.3<E.sub.L/E.sub.1≤0.8, and 3.4≤E.sub.6/E.sub.S≤14, and wherein the sixth wavelength range comprises a peak between 650-690 nm.

A lighting assembly includes a light guide having opposite first and second major surfaces and at least one edge surface extending between the first and second major surfaces, a solid-state light source arranged to emit light into the edge surface of the light guide, and a plurality of integrated optical elements associated with the first major surface to redirect the light emitted by the solid-state light source. The lighting assembly may further include an air circulation device and a heat transfer system configured to transfer heat generated by the solid-state lighting source to a flow of air generated by the air circulation device. The solid-state light source may include light-emitting diodes, laser diodes, and/or organic light emitting diodes configured to produce multiple colors. Also provided is a habitat including the lighting assembly, and related methods.

A lighting assembly includes a light guide having opposite first and second major surfaces and at least one edge surface extending between the first and second major surfaces, a solid-state light source arranged to emit light into the edge surface of the light guide, and a plurality of integrated optical elements associated with the first major surface to redirect the light emitted by the solid-state light source. The lighting assembly may further include an air circulation device and a heat transfer system configured to transfer heat generated by the solid-state lighting source to a flow of air generated by the air circulation device. The solid-state light source may include light-emitting diodes, laser diodes, and/or organic light emitting diodes configured to produce multiple colors. Also provided is a habitat including the lighting assembly, and related methods.