A smart temperature control system is disclosed. The smart temperature control system includes processing circuitry and a temperature control device. The temperature control device includes a container configured to store a product and temperature control hardware configured to control a temperature within the container. The processing circuitry includes one or more processors configured to monitor the temperature cycles within the container, determine a duration of at least portions of each temperature cycle over a time period, determine a selected time value based on the duration of the portions of each temperature cycle, and update a time limit variable with the selected time value.

A refrigerator for storing products includes a sensor container configured to position at least one temperature sensor within a refrigerated interior in a cabinet of the refrigerator. The sensor container includes a main body portion enclosing a hollow interior space configured to receive a ballast liquid, and a plurality of dry wells which each extend generally horizontally between a closed end within the hollow interior space and an open end. The temperature sensors positioned in the dry wells are surrounded by ballast liquid but are not in direct contact with refrigerated air within the cabinet or the ballast liquid. The temperature measurements therefore approximate the thermal response of products (such as blood) stored in the cabinet without necessitating submersible sensors or a risk of liquid leaks. The temperature measurements may be sent to elements such as a chart recorder, and a display and alarm device associated with the refrigerator.

A refrigerator includes an ice maker, which includes an ice making cell, a heater configured to supply heat to the ice making cell during an ice making process, and a controller configured to control the heater. A cooling power of the cooler when a temperature sensed by a temperature sensor is greater than or equal to a limit temperature during an ice making process is greater than a cooling power of the cooler when the temperature is less than the limit temperature. A heating amount of the heater when the temperature sensed by the temperature sensor is greater than or equal to the limit temperature during the ice making process is greater than a heating amount of the heater when the temperature is less than the limit temperature.

Methods and apparatus to determine home appliance cabinet temperatures using light emitting diodes (LEDs) are disclosed. An example home appliance includes a cabinet, a lighting system disposed in the cabinet having one or more LEDs to provide lighting in the interior of the cabinet, and a circuit electrically coupled to the lighting system and programmed to determine a temperature inside the cabinet based on a characteristic of the one or more LEDs of the lighting system.

A refrigerator operates in a single mode and a dual mode. A plurality of sides defines a storage compartment. At least one door provides access to the storage compartment via an opening in at least one of the sides. At least one outlet vent expels air across the at least one opening towards at least one inlet vent configured to receive at least a portion of the expelled air. A first cooling circuit is fluidly coupled to at least the storage compartment. A second cooling circuit is fluidly coupled to at least one of the outlet vent, the inlet vent, and at least one air screen inlet vent. The refrigerator operates in the single mode when the door is closed during which the first cooling circuit operates. The refrigerator operates in the dual mode when the door is open during which the first cooling circuit and the second cooling circuit operate.

A refrigeration device includes a cabinet defining a compartment and is operable to control an environment within the compartment. At least one sensor is associated with the compartment. A processor receives compartment data from the at least one sensor associated with the compartment. The processor operates an environmental control system of the refrigeration device according to the compartment data. The processor is communicatively connected to and operates a graphical display of an input module to present compartment data in a graphical user interface of the input module.

A refrigerator according to the present invention includes a storage chamber configured to store food, a cold air supply part configured to supply cold air to the storage chamber, a tray configured to form an ice making cell being a space in which water is phase-changed into ice by the cold air, a temperature sensor configured to sense the temperature of water or ice in the ice making cell, a heater configured to provide heat to the tray, and a controller configured to control the heater, in which the controller controls the heater to be turned on so that ice can be easily separated from the tray when the ice making is completed, and the controller controls the heater to be turned off when a temperature sensed by the temperature sensor reaches a first turn-off reference temperature greater than zero after a first reference time elapses in a state in which the heater is turned on.

An artificial intelligent food refrigerating device and a method for refrigerating food by using the same are disclosed. An artificial intelligent food refrigerating device according to the present disclosure identifies the size, volume, type, and quantity of food to be put into it and determines a target refrigeration temperature and refrigeration time for the food based on an identification result. The artificial intelligent food refrigerating device and method according to the present disclosure may be associated with an artificial intelligent module, a robot, an augmented reality (AR) device, a virtual reality (VR) device, a 5G service-related device, etc.

Provided are a refrigerator, and a method for correcting temperature measurement errors of an infrared sensor including: verifying that the infrared sensor is running in an operating state; obtaining a measured operating-state value acquired by the infrared sensor sensing the temperature of a preset zone; obtaining a correction constant corresponding to the infrared sensor, the correction constant being obtained by means of a comparison between the value measured by the infrared sensor in a correction state and a standard temperature value; using the correction constant to correct the measured value and thus obtain a corrected temperature value. Using the method, the impact of an absolute error of the infrared sensor on temperature measurement is reduced; thus the accuracy of temperature measurement is improved, such that measured values directly reflect the actual temperature of the items inside a preset zone, and an accurate basis for control is provided for subsequent associated control.

A refrigerator includes a refrigerating compartment temperature sensor, a cooling apparatus, in a state when driving time points of a refrigerating compartment and a freezing compartment are synchronized, to maintain an inside temperature of the refrigerating compartment by performing a cooling operation of the refrigerating compartment on the basis of a cut-off temperature of the refrigerating compartment that is varied by a difference between a temperature of the refrigerating compartment at a driving time point of the refrigerating compartment that is sensed by the refrigerating compartment temperature sensor and a cut-in temperature of the refrigerating compartment, and a control unit to control the driving of the cooling apparatus by varying the cut-off temperature of the cooling apparatus according to the difference between the temperature of the refrigerating compartment at the driving time point of the refrigerating compartment and the cut-in temperature of the refrigerating compartment.