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 aquaculture system including an aquaculture tank for holding aquaculture water for culturing an aquatic organism, a thermal insulation house that covers the aquaculture tank, an insulation positioned on at least part of a region surrounding the aquaculture tank, and a temperature adjuster that adjusts a temperature inside the thermal insulation house and/or a temperature of the aquaculture water in the aquaculture tank.

An aquaculture system including an aquaculture tank for holding aquaculture water for conducting biofloc aquaculture therein, and an immobilizing material in the aquaculture tank. The immobilizing material includes a carrier that carries nitrifying bacteria.

An automated terrarium feeder assembly includes a cover that is longitudinally elongated thereby facilitating the cover to be positioned on top of a terrarium to inhibit a reptile contained in the terrarium from escaping. A feeder is movably integrated into the cover to release a pre-determined amount of the reptile food into the terrarium to feed the reptile while an owner of the reptile is not present for extended periods of time. A heat lamp is integrated into the cover to warm the reptile. A light emitter is integrated into the cover to illuminate the terrarium. A touch screen is attached to the cover and the touch screen is in communication with the feeder for programming operational parameters of the feeder, the heat lamp, the light emitter and the blower.

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.

The present disclosure provides systems for heat source, e.g., data center, cooling and aquaculture. In certain aspects, the systems include a heat source, e.g., data center, having a water cooling subsystem configured to receive cool water and output warm water and an aquaculture center co-located with the heat source, e.g., data center, and configured to receive the warm water. Aspects of the invention also include methods for cooling a heat source, e.g., data center, using a water cooling subsystem and cultivating aquatic organisms with an aquaculture center that is co-located with the heat source, e.g., data center.

A heater for aquariums comprises a heating element configured to generate an amount of heat for heating an amount of water of an aquarium and a support body configured to support the heating element. In particular, the support body has a support surface configured to support the heating element and a heat exchange surface configured to come into contact with the water to be heated in a dynamic manner to transmit at least a portion of the amount of heat generated by the heating element thereto. The support body is at least partially made of alumina.

A heat exchange system includes a water flow casing shaped like an open box and having a flow space defined therein and water inlet/outlet pipes for guiding a water into the flow space or for guiding the water out of the flow space, a thermoelectric cooling chip fastened to the open side of the water flow casing with the cold side facing toward the flow space for cooling the water, a heat dissipating unit fastened to the opposing hot side of the thermoelectric cooling chip for dissipating heat from the thermoelectric cooling chip, and a water pump adapted for pumping the water through the water inlet/outlet pipes and flow space of the water flow casing for cooling.

The present disclosure provides systems for heat source, e.g., data center, cooling and aquaculture. In certain aspects, the systems include a heat source, e.g., data center, having a water cooling subsystem configured to receive cool water and output warm water and an aquaculture center co-located with the heat source, e.g., data center, and configured to receive the warm water. Aspects of the invention also include methods for cooling a heat source, e.g., data center, using a water cooling subsystem and cultivating aquatic organisms with an aquaculture center that is co-located with the heat source, e.g., data center.

A mobile treatment system having a mobile or wheelable container able to receive a secondary volume of water separate from the primary volume of water of the aquarium; a pump mountable to a portion of the mobile container, a first Inlet of the pump able to draw water from a portion of the mobile container, a first outlet of the pump connectable for selectively directing water drawn into the first Inlet back into the mobile container after conditioning of the water, a second inlet able to draw conditioned water from a portion of the mobile container having the conditioned water; a second outlet allowing transfer of the conditioned water from the mobile container to the aquarium, wherein the water is conditioned in the secondary volume of the mobile container at a position remote to the aquarium.