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 process for harvesting fish eggs is provided, in particular fish eggs from Salmon. The process comprises rearing sexually immature salmon in an aquatic environment in stages during which at least the light exposure and time span is adjusted. The rearing includes at least a winter-summer period that comprises a winter life-cycle stage, within which the broodstock is exposed to light that simulates winter light exposure, and a subsequent summer life-cycle stage, within which the broodstock is exposed to light that simulates summer light exposure, wherein the total Accumulated Thermal Unit (ATU) during the winter-summer period is no more than 5000. The inventions also provides salmon eggs that are produced by the disclosed process.

An (aqua)terrarium, in particular for ectothermic animals, has a container serving as living space. The (aqua)terrarium is provided with a climate control device that comprises a flow machine, in particular a fan, and an electrothermal converter, in particular a Peltier element. It is provided that the climate control device sucks in air from the container, conditions the sucked-in air by guiding it along a first side of the electrothermal converter, and conveys the conditioned air back into the container.

The present invention relates to a method and a device for treating and/or transporting food items. The apparatus and method are designed to facilitate treating animals or food items in liquid. The device of the present invention is designed as a spiral shaped channel with one or more channels wound together around an axis. The apparatus of the present invention and the use thereof provides a method to heat or cool food items in a spiral shaped channel device.

The present invention relates to a method of raising fish in a recirculated aquaculture system which includes a fish holding unit in fluid communication with a water supply, the fish holding unit containing a volume of water defining a water depth, and having an osmotic concentration, an oxygen concentration, a temperature, and a pH. The method includes providing a flow of non-recirculated water to the water supply, the non-recirculated water being different from the water in the fish holding unit with respect to the osmotic concentration, the oxygen concentration, the CO2 concentration, the N2 concentration, the NH4+ concentration, the temperature and/or the pH, providing feed pellets, adding the feed pellets to the non-recirculated water and hydraulically transporting the feed pellets to the fish holding unit. The invention also relates to a RAS facility.

A fully air-powered, n-way redundant aquaponic system for integrated cultivation of various fish, plant, and mushroom species, off-grid, with each grow bed including a respective DC air pump, solar panel, and battery to ensure self-sufficiency, redundancy, and enhanced resilience. Each mushroom grow bed also includes an evaporative cooling system for year-round mushroom production.

The present invention relates to a heat stress resisting technology for transport of live fish. Display screens are arranged in a transport case on the four side surfaces and the top surface, a plurality of transparent interlayer trays are arranged in the fish tank from the bottom to the top, a plurality of small through holes are formed in the interlayer trays, an oxygen generator is arranged in the transport case, an oxygen content meter is arranged in a pipeline of the oxygen generator, a refrigeration system is arranged in the transport case on one side surface, an air exchange pipe is arranged in the fish tank, the air exchange pipe extends out of the transport case, a second solenoid valve is arranged in the air exchange pipe. The present invention makes fish have no swimming activity and lack of response to external stimuli.

A larvae counter comprising a first container for receiving water, eggs of insects and/or larvae, a second container in fluid communication with the first container for receiving water and larvae from the first container, and a larvae counting module in fluid communication with the second container for receiving water and larvae from the second container and counting the larvae.

An environmental control device for aquariums, ponds, or terrariums includes: a casing; an environmental control device, adapted to control an environmental condition of the aquarium, pond, or terrarium; and an NFC communication device configured to communicate with an external unit. The external unit is configured to exchange data with the NFC communication device so as to monitor and/or control an operating parameter of the environmental control device or an operating condition of the environmental control device or environmental condition of the aquarium, pond or terrarium.

Light, heat, gas exchange, and water motion are all required elements to sustain aquatic photosynthetic organisms. Rather than providing separate systems, a flux of photons appropriate for photosynthetic organisms, including algae, is dispersed throughout the surrounding water. A gas source performs water movement and circulation by acting as an airlift pump while performing a liquid-gas mass transfer. Finally, heat is added to the surrounding liquid by a heat source or the light source, which increases the rate at which microorganisms grow and improve efficiencies. By combining these necessary components for aquatic life support, efficiencies are increased, costs are saved, and photosynthetic organism growth is regulated.