An active/passive freezer system includes the capability to both actively cool a payload bay and passively maintain close to that temperature for extended periods of time; a freezer unit with a payload bay that can rapidly reduce its internal temperature; a thermal battery; a heat exchanger where liquid Nitrogen flows through; insulation that significantly reduces heat gain from external sources; and the capability to have separate units for cooling the payload bay and maintaining the temperature within the payload bay.

Methods, systems, and device for solidification and/or solid production, such as ice production, are provided in accordance with various embodiments. For example, some embodiments include a method of solid production that may include contacting a first fluid with a second fluid to facilitate solidifying the second fluid; the first fluid and the second fluid may be immiscible with respect to each other. The method may include solidifying the second fluid. Some embodiments include a solid production system that may include a first fluid and a second fluid; the first fluid and the second fluid may be immiscible with respect to each other. The system may include one or more surfaces configured to contact the first fluid and the second fluid with each other and to form one or more solids from the second fluid.

A sintered heat tube and a semiconductor cooling refrigerator having the same, the sintered heat tube comprises: a main tube segment with its both ends closed, and a manifold tube segment/manifold tube segments extending from one or more portions of one side of the main tube segment (respectively), wherein a work chamber of each manifold tube segment communicates with that of the main tube segment. In the sintered heat tube and the semiconductor cooling refrigerator having the sintered heat tube of the present invention, as the sintered heat tube includes manifold tube segments, the sintered heat tube of the present invention greatly improves the heat radiating or cold transferring efficiency. The sintered heat tube is particularly suitable for heat radiation of heat sources of a high heat flow density such as semiconductor cooling plates.

A refrigerator includes a cabinet, a first inner case that defines a freezing compartment, a second inner case that defines a refrigerating compartment, a thermal siphon unit that is configured to carry a working fluid for heat transfer and that has a closed loop shape that includes a first part arranged at an outer side of the first inner case and a second part arranged at an outer side of the second inner case, and a cool air storage unit arranged in a space partitioned in the first inner case. The cool air storage unit is configured to accommodate cool air of the freezing compartment and transfer the cool air to the first part of the thermal siphon unit arranged outside of the first inner case.

A packaged meal kit includes a container, a liner, a first cold pack, a frozen food item, a protective insert, a non-frozen food item, a second cold pack, and instructions. The liner is disposed adjacent an interior of the container. The first cold pack is disposed in a bottom of the container adjacent the liner. The frozen food item is disposed above the first cold pack. The protective insert is disposed above the frozen food item. The protective insert includes a hollow cross-section. The non-frozen food item is disposed in the hollow cross-section. The second cold pack is disposed above the protective insert. Instructions are disposed in the container for preparing a meal including the frozen and non-frozen food items.

An internal melt ice thermal storage device having an ice build/melt coils with tubes fitted with extensions or fins that transfer heat from the thermal transfer medium in the tubes to distal portions of the ice rings that surround said tubes in order to define the shape of the liquid meniscus between the tube and ice allowing the ice to break free from the tube near the initiation of melt.

According to various aspects, exemplary embodiments are disclosed of chiller systems including thermoelectric modules, and corresponding control methods. In an exemplary embodiment, a compressor chiller system generally includes a refrigerant loop having a refrigerant fluid, a compressor connected in the refrigerant loop to compress the refrigerant fluid, and a condenser connected in the refrigerant loop to receive the compressed refrigerant fluid from the compressor and to condense the compressed refrigerant fluid. The system also includes a heat transfer component connected in the refrigerant loop to receive the condensed refrigerant fluid from the condenser, and a coolant loop having a coolant fluid. The heat transfer component is connected in the coolant loop to transfer heat from the coolant fluid to the condensed refrigerant fluid. The system further includes a thermoelectric module connected in the coolant loop. The thermoelectric module is adapted to transfer heat into and/or out of the coolant fluid.

A cooling system may include a cooling pump, a cooling source, a thermal energy storage, a mixing valve, a recharge valve, a recharge pump. The mixing valve may be in fluid communication with a thermal load. A first input of the mixing valve may be in fluid communication with the thermal energy storage. A second input of the mixing valve may be in fluid communication with the recharge pump. Operation of the recharge pump may cause heated cooling fluid output from the thermal load to bypass the cooling pump and flow to the second input of the mixing valve. The recharge valve may be in fluid communication with the thermal energy storage and the cooling pump. The recharge valve may regulate a recharge fluid flow comprising cooling fluid received from the thermal energy storage.

The present disclosure relates to a container (100) for a phase change material, wherein said container is characterized in that it comprises: a closed shell (101) where a filling opening (103) is arranged; a phase change material nested in said shell (101); one or several recesses (105) designed to receive a conduit for refrigerant fluid.

Embodiments of the present disclosure are directed toward systems and method for cooling a refrigerant flow of a refrigerant circuit with a cool water flow from a cool water storage to generate a warm water flow and to cool the refrigerant flow by a subcooling temperature difference, flowing the warm water flow to the cool water storage, and thermally isolating the warm water flow from the cool water flow in the cool water storage.