A method for controlling a refrigerator according to the present embodiment is a method for controlling a refrigerator comprising a first tray forming a part of an ice chamber, a second tray forming another part of the ice chamber, a driving unit for moving the second tray, an ice bin for storing ice produced in the ice chamber, and an ice-fullness detection means for detecting whether or not the ice bin is full of ice, the method comprising the steps of: supplying water to the ice chamber in a state in which the second tray has moved to a water-supply position; making ice after the second tray has moved from the water-supply position to an ice-making position in the inverse direction after the water supply has been completed; determining whether or not the ice bin is full of ice after the ice making is completed; moving the second tray to an ice-separating position and then rotating same in the inverse direction if it is not determined in the step of determining whether or not the ice bin is full of ice that the ice bin is full of ice; and determining again whether or not the ice bin is full of ice after ice separation is completed.

A method for controlling a refrigerator according to the present embodiment is a method for controlling a refrigerator comprising a first tray forming a part of an ice chamber, a second tray forming another part of the ice chamber, a driving unit for moving the second tray, an ice bin for storing ice produced in the ice chamber, and an ice-fullness detection means for detecting whether or not the ice bin is full of ice, the method comprising the steps of: supplying water to the ice chamber in a state in which the second tray has moved to a water-supply position; making ice after the second tray has moved from the water-supply position to an ice-making position in the inverse direction after the water supply has been completed; determining whether or not the ice bin is full of ice after the ice making is completed; moving the second tray to an ice-separating position and then rotating same in the inverse direction if it is not determined in the step of determining whether or not the ice bin is full of ice that the ice bin is full of ice; and determining again whether or not the ice bin is full of ice after ice separation is completed.

An ice maker for a refrigerator appliance includes an ice making assembly defining a receiving chamber in fluid communication with an air duct and a mold assembly removably mounted to the ice making assembly. The mold assembly includes a frame configured for receipt within the receiving chamber of the ice making assembly, a heat exchanger mounted to the frame and defining a mold support surface, and a flexible mold positioned on the mold support surface that is supported by the heat exchanger such that the flexible mold is in thermal communication with the heat exchanger and defines a mold cavity configured to receive a liquid. The mold assembly is replaceable with alternate mold assemblies.

An ice making assembly includes an ice mold including two or more separable portions that collectively define one or more mold cavities. Each of the mold portions define a plurality of recessed passages that at least partially surround the mold cavity and are configured to receive evaporator conduit of a sealed refrigeration to cool the ice mold and facilitate formation of an ice billet.

An ice making assembly includes an ice mold including two or more separable portions that collectively define one or more mold cavities. Each of the mold portions define a plurality of recessed passages that at least partially surround the mold cavity and are configured to receive evaporator conduit of a sealed refrigeration to cool the ice mold and facilitate formation of an ice billet.

The present disclosure relates to an ice maker and a refrigerator having the ice maker. An ice maker according to the present disclosure includes: an upper assembly including an upper tray forming an upper chamber, which is a portion an ice chamber, and having an upper opening, and a temperature sensor configured to sense temperature of the ice chamber in contact with the upper tray; and a lower assembly being rotatable with respect to the upper assembly and having a lower tray forming a lower chamber that is another portion of the ice chamber, in which a contact portion between the temperature sensor and the upper tray is positioned closer to a contact surface of the upper tray and the lower tray than the upper opening.

The present disclosure relates to an ice maker and a refrigerator having the ice maker. An ice maker according to the present disclosure includes: an upper assembly including an upper tray forming an upper chamber, which is a portion an ice chamber, and having an upper opening, and a temperature sensor configured to sense temperature of the ice chamber in contact with the upper tray; and a lower assembly being rotatable with respect to the upper assembly and having a lower tray forming a lower chamber that is another portion of the ice chamber, in which a contact portion between the temperature sensor and the upper tray is positioned closer to a contact surface of the upper tray and the lower tray than the upper opening.

Methods and apparatus for artificial bird manufacturing in impact testing is described herein. An apparatus to generate an artificial bird for impact testing includes a mold generator to form a mold based on a bird class identification, a mold filler to fill the mold with a first layer of crushed ice and a second layer of crushed ice, a compressor to compress an ice surface of at least one of the first layer or the second layer of the crushed ice to form indentations on the ice surface, and a freezer to re-freeze the crushed ice layers inside the mold to form an artificial bird.

Methods and apparatus for artificial bird manufacturing in impact testing is described herein. An apparatus to generate an artificial bird for impact testing includes a mold generator to form a mold based on a bird class identification, a mold filler to fill the mold with a first layer of crushed ice and a second layer of crushed ice, a compressor to compress an ice surface of at least one of the first layer or the second layer of the crushed ice to form indentations on the ice surface, and a freezer to re-freeze the crushed ice layers inside the mold to form an artificial bird.

A device for removing foreign matter in an ice maker is configured to prevent foreign matter from accumulating on the bottom of a float by changing the structure of the bottom of the float. The device includes a level sensor sensing a water level using a float moving up and down, depending on a height of water supplied in a water tank and a connection pipe forming a channel for water flow between the water pump and the level sensor by being connected to the level sensor, and having an inclined surface inclined downward toward an entrance of the channel under the float.