An aquaculture system can include stacked growth trays. Animals, such as shrimp, can be transferred between the growth trays for different stages of growth. Waste water can be removed from the growth trays and can be processed by a water treatment system. Treated water can be returned to the growth trays. A valve in a first configuration can permit water to circulate through the growth tray, while impeding the animals from exiting the growth tray. In a second configuration, the valve can permit the animals to exit the growth tray, such as for transition to a subsequent growth tray. A sweeper system can be used for cleaning and/or mixing the water in the growth tray, and/or for pushing the animals out of the growth tray during a transition.

An aquaponics and greenhouse system, includes an insulated solar greenhouse with a glazing on a sun facing side at an angle to maximize winter sunlight, and housing a fish tank housed within the solar greenhouse; a plant growing area housed within the solar greenhouse; a mushroom growing area housed within the solar greenhouse; a water wall thermal mass housed within the solar greenhouse and disposed between the plant growing area and mushroom growing area; and a natural air ventilation system housed within the solar greenhouse and configured to provide misted air into the mushroom growing area. O2 generated by the plant growing area is received by the natural air ventilation system and provided to the mushroom growing area, and CO2 generated by the mushroom growing area is provided to the plant growing area.

The present invention provides a waterless keep-alive apparatus and a refrigeration appliance having the same. The waterless keep-alive apparatus is provided in an inner tank of a refrigeration appliance, and comprises: a keep-alive box allowing pulling inward and outward; a temperature controlling module and a humidity controlling module which are connected with the keep-alive box; and an air controlling module having an air hole provided on a side wall of the keep-alive box and an air duct fixed on the inner tank of the refrigeration appliance. The air duct is hermetically connected with the air hole when the keep-alive box is pushed into the inner tank of the refrigeration appliance. The air duct is disconnected from the air hole when the keep-alive box is pulled out. The waterless keep-alive apparatus realizes convenient article fetching while the oxygen concentration in the keep-alive box can meet the survival needs of aquatic products.

A climate controlled display cabinet includes a frame. A stationary shelf is coupled to the frame. A plurality of operable shelves is coupled to at least one of the frame and the stationary shelf. The operable shelves are moveable between open and closed positions. A heat source is in thermal communication with the stationary shelf and the plurality of operable shelves. At least one temperature sensor monitors a temperature of an area proximate the stationary shelf and the plurality of operable shelves.

A method and system for self-contained growth and harvesting of plant and animal foodstuffs and energy generation for terrestrial and non-terrestrial uses. The system can be self-contained and sealed from an ambient atmosphere wherein sufficient oxygen and carbon dioxide levels are maintained (bio-regenerative) to support human life. The system and method may utilize aquaculture and hydroponic plant growth with a digester for converting waste into nutrients. Water may circulate among the digester, aquaculture tanks and hydroponic growth tanks. The method may be scalable to support varying quantities of human life. The system and method may generate energy and consume greater quantities of carbon dioxide than generated. The system may be energy self-sufficient utilizing solar, wind or other energy sources such as generated methane gas.

A monitoring system can implement a method including receiving data characterizing first measurements recorded by a sensor in a heating area, second measurements recorded by the sensor in an ambient area, and third measurements recorded by the sensor in a central area, located between the heating area and the ambient area. The method further includes determining a first average temperature, a second average temperature, and a third average temperature. The method further includes computing a first temperature difference between the first average temperature in the heating area and the third average temperature in the central area, and a second temperature difference between second average temperature in the ambient area and the third average temperature of the central area. The method further includes providing the first temperature difference and the second temperature difference.

The present invention is directed to a habitat for housing either cold blooded animals, warm blooded animals or plants, and in particular it is directed to a habitat for housing cold blooded animals such as lizards including geckos and the like. The present habitat apparatus comprises a transparent terrarium in combination with a stand, the stand including a partition that provides a space to receive and nest the transparent terrarium within so a portion of the transparent terrarium is masked by the partition to create a secure zone within the interior space of the terrarium that is distinct from adjoining interior space.

An aquaculture system (1) for farming aquatic organisms includes an apparatus (2) for supplying oxygenated water into an enclosure (20) in which aquatic organisms are to be fanned. The apparatus (2) includes a water inlet (4) and an oxygen inlet (6) to create a water and oxygen mixture. The apparatus (2) also includes a venturi (17) arranged to dissolve the oxygen into the water passing through the venturi and such that the oxygen and water mixture passing through the venturi (17) is exposed to a substantially null magnetic field. The apparatus is also arranged such that the water and oxygen mixture that is supplied to the venturi (17) contains substantially no colloidal minerals. The apparatus also includes an outlet (18) for the oxygenated water in fluid communication with, and downstream of, the venturi (17) and in fluid communication with the inlet of the enclosure (20).

A flat heater includes a housing including an accommodating groove formed inside the housing; a circuit unit disposed within the housing to control the heater, wherein the circuit unit includes a circuit board and a first rectifier disposed on the circuit board; a heating module disposed in the accommodating groove and electrically connected to the circuit unit, wherein the heating module includes a plurality of heating pipes and a plurality of second rectifiers disposed in each of the heating pipes; an upper cover assembled to a top surface of the housing and comprising a long side and a short side, wherein a plurality of fluid-permeable holes are formed on the upper cover; and a suction member inserted into the through hole and attached to an object and thereby fixing the housing to the object.

Methods are proposed to define UE behavior for performing synchronization signal block (SSB) based radio link monitoring (RLM) and channel state information reference signal (CSI-RS) based RLM. In a first novel aspect, if CSI-RS based RLM-RS is not QCLed to any CORESET, then UE determines that CSI-RS RLM configuration is error and does not perform RLM accordingly. In a second novel aspect, SSB for RLM and RLM CSI-RS resources are configured with different numerologies. UE perform SSB based RLM and CSI-RS based RLM based on whether the SSB and CSI-RS resources are TDMed configured by the network. In a third novel aspect, when multiple SMTC configurations are configured to UE, UE determines an SMTC period and whether SMTC and RLM-RS are overlapped for the purpose of RLM evaluation period determination.