An aspect of the present disclosure is to provide a refrigerator and a method of controlling the same that protects privacy by designating a user in each storage chamber and allowing only the designated user to use the storage chamber in order to protect the privacy of each user and preventing mishandling of items stored in the refrigerator in advance when the plurality of users share a refrigerator, and prevents mishandling of stored items by prohibiting the use of the storage chamber other than the designated storage chamber. The refrigerator includes a display; a storage chamber configured to allow use only by authorized users; and a controller configured to display information of the storage chamber through the display in response to the completion of user authentication of the storage chamber.

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 system generates alerts based on sensor data obtained from equipment, for example, refrigeration equipment. Examples of equipment instances include refrigeration equipment, heating equipment, air conditioning equipment, and so on. The system accesses a model, for example, a machine learning model trained to predict an alert threshold for generation of alerts. The system modifies the alert threshold value for an equipment instance based on the output of the machine learning model. The system uses the modified alert threshold value for generating alerts. The system may track the number of times the alert threshold was adjusted. If the number of times the alert threshold value is modified exceeds a predetermined fault threshold value, the system determines that the equipment is faulty.

An electronic lock refrigeration assembly for storage of food includes a refrigeration unit. The refrigeration unit has a peripheral surface and a back surface. A plurality of doors is positioned on the peripheral surface of the refrigeration unit. Each of the doors has a key pad and a handle. Additionally, each of the doors has a cavity. The plurality of doors encloses the cavity of each of the doors. A locking system is positioned on the peripheral surface of the refrigeration unit. The locking system includes a screen and a pay pad. The screen is a computer of the locking system. The screen allows the user to select an open locker to use. The pay pad is an electronic payment pad. The pay pad is in electric communication with the screen.

A method and apparatus for monitoring a circulation process of a heat insulation unit. The method comprises: acquiring original data of the heat insulation unit in an original warehouse (101), the heat insulation unit being a heat insulation box having a refrigerant unit; after commodities of an order are added to the heat insulation unit, acquiring scanning data of the heat insulation unit at at least one supply site (102), the supply site being determined according to the order and bound to the ID of a supply scanning device, and the scanning data comprising the barcode of the heat insulation box and the ID of the supply scanning device; after it is determined that the commodities have been taken out of the heat insulation unit, acquiring intermediate data of the heat insulation unit at at least one distribution site (103).

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 container refrigeration apparatus includes a refrigeration cycle unit having a refrigerant circuit, and a controller configured to control an action of the refrigeration cycle unit to adjust a temperature of inside air in a container to a desired temperature. The controller is configured to include an impact determination section configured to determine whether or not a strong impact acted on the container, and an abnormality diagnosis section configured to perform an abnormality diagnosis to diagnose whether or not at least one of the container or the container refrigeration apparatus has an abnormality when the impact determination section determines that a strong impact acted on the container.

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 system for managing transport refrigeration units (28) is provided. The system includes a storage device (80) to store transport parameters (82) associated with a transport refrigeration unit (28). The storage device storing historical transport parameters (84) for other transport refrigeration units (28). Also included is an equipment management system (90) coupled to the storage device, the equipment management system (90) including: a diagnostic module (92) to determine a condition of the transport refrigeration unit (28) in response to the transport parameters (82); a predictive maintenance module (94) to determine a need for upcoming maintenance of the transport refrigeration unit (28) in response to the transport parameters (82); and a remaining life module (96) to determine a remaining life of at least one component of the transport refrigeration unit (28) in response to the transport parameters (82).

Disclosed is a refrigerating and freezing device, including a cabinet defining at least one storage compartment, at least one cabinet door configured to respectively open and close the at least one storage compartment, a refrigerating system configured to provide cooling capacity to the at least one storage compartment, and a heating unit. The heating unit includes a cylinder body disposed in one storage compartment and provided with a pick-and-place opening, a door body configured to open and close the pick-and-place opening, and an electromagnetic generating system configured to generate electromagnetic waves in the cylinder body to heat an object to be processed. The refrigerating and freezing device further includes a cabinet door detection device, and the cabinet door detection device is configured to detect open and closed states of the cabinet door corresponding to the storage compartment provided with the cylinder body; and the electromagnetic generating system stops generating electromagnetic waves when a corresponding cabinet door is in an open state, which can prevent electromagnetic waves in the heating unit from leaking and affecting the health of a user, thereby improving the safety of the refrigerating and freezing device.