A method of measuring pressure includes the steps of (1) providing a vacuum cabinet with a storage compartment and an insulating space, and three temperature sensors; (2) sensing a first temperature level of an interior wall of the storage compartment; (3) sensing an ambient temperature level within the storage compartment; (4) sensing a second temperature level of an exterior wall of the storage compartment; (5) calculating an overall heat transfer coefficient (Q) using the ambient temperature level, the first temperature level, and a convective heat transfer coefficient for the interior wall of the storage compartment; (6) calculating a temperature differential between the second and first temperature levels; (7) determining a conductivity level (K) using the temperature differential, the overall heat transfer coefficient (Q) and a thickness of the insulating space; and (8) determining a pressure level (P) within the insulating space using the conductivity level (K).

A method for reducing sweating in a temperature-controlled display device includes receiving values of an ambient temperature, a door frame temperature, and relative humidity. The method can also include estimating a value of a dewpoint temperature using the values of the ambient temperature and the relative humidity. The method can also include determining control decisions for a door frame heater of the temperature-controlled display device using the value of the dewpoint temperature and the door frame temperature, and transitioning the door frame heater between an on-state and an off-state using the control decisions to maintain the value of the door frame temperature at or above the value of the dewpoint temperature.

A method for determining a time frame for when a freezer having a compressor should be defrosted include the steps of measuring compressor cycling over time, determining a change in compressor cycling over time, and determining from the change in in compressor cycling over time determined a time frame for when the freezer should be defrosted.

A portable refrigeration system for use in transport of medicines or other valuable, temperature sensitive materials is disclosed. The system can use GPS positioning technology to provide absolute global location along with internet connection through a cellular modem on board which allows for communication to the cloud of temperature and transit data during device use. The refrigerator 10 can be powered by a rechargeable battery back that may be recharged through connection to AC mains supply or connection to the photovoltaic panel 26 included with the device 10. The insulated container can be held at a constant temperature through the use of vacuum insulated panel construction. The device 10 can be cooled through the use of thermoelectric cooling modules 68 coupled to the insulated chamber 74 and paired with a heat exchanger 56 with heat pipes 60 and a system fan 54. The device 10 can be operated either through the included graphical user interface display 20 via touch or buttons or it may be accessed and controlled by a remote computer 80 through the cloud via a cellular connection 78.

A vehicle including a refrigerated compartment having a chamber and a cooling system for cooling the chamber and methods of controlling the cooling system is provided. The vehicle includes a controller that controls a supply of power from a battery of the vehicle to the cooling system based on at least one output signal received from a vehicle component.

A selection apparatus according to an aspect of the disclosure includes a calculation unit configured to calculate, based on data correlated with power consumption of portable cold-energy equipment and data related to a set temperature of the cold-energy equipment, an amount of power consumption expected during transportation of the cold-energy equipment to a predetermined destination; and a selection unit configured to select, based on the amount of power consumption calculated by the calculator, a rechargeable battery to be mounted on the cold-energy equipment.

A cold storage includes a box with a cold storage chamber, a compressor constituting a refrigeration circuit that cools the inside of the cold storage chamber, a defrost heater that heats an evaporator constituting the refrigeration circuit, and a control apparatus that controls the compressor and the defrost heater. The control apparatus operates the defrost heater when the compressor is not operated. When an outside air temperature is equal to or higher than a chamber temperature in the cold storage chamber, the control apparatus operates the compressor upon the chamber temperature rising up to a first threshold and stops the compressor upon the chamber temperature dropping down to a second threshold lower than the first threshold. When the outside air temperature is lower than the chamber temperature, the control apparatus does not operate the compressor even when the chamber temperature rises up to the first threshold.

Disclosed is a method of maintaining an initial quantity of mRNA vaccine cargo in an EPS container containing dry ice as a passive coolant during shipment from a manufacturing site, wherein the initial quantity of mRNA vaccine cargo is shipped to a first depot and then repackaged into smaller quantities at one or more additional depots en route to the final destinations. Dry ice can be added or ordered in advance to be available at the next depot for the cargo. Indicators show the status of the cargo and whether it has undergone unacceptable temperature or humidity excursions.

A refrigerator includes a temperature sensor; a door sensor; a compressor sensor; an ice sensor; a water sensor; and a defrost sensor. The refrigerator also includes a communication unit; a display unit; at least one processor; and at least one memory connected to the at least one processor and storing instructions that, when executed, perform operations including: sensing, through the plurality of sensors, sensing information related to the refrigerator; storing, in the at least one computer memory, (i) the sensing information, and (ii) time information; transmitting to at least one server, (i) the sensing information and the time information, and (ii) setting information for the refrigerating compartment or the freezer compartment; receiving information regarding an abnormal state of the refrigerator that is generated by a cloud server or a monitoring server based on the sensing information; and outputting display information related to the received information regarding the abnormal state.

A refrigeration appliance includes a refrigeration circuit with a variable speed compressor, an evaporator, and a variable speed evaporator fan. A controller is operatively connected to the refrigeration circuit and is programmed to calculate a heat load ratio as a ratio between the difference between the ambient temperature and the set point temperature of the fresh-food compartment and the difference between the ambient temperature and the freezer compartment reference point; calculate a speed of one or both of the variable speed compressor and the variable speed evaporator fan as a function of the calculated heat load ratio; and operate one or both of the variable speed compressor and the variable speed evaporator fan at the calculated speed. A method of controlling temperature in cavities of a refrigerator is also provided.