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 optoelectronic module for a light barrier for fill height monitoring of an ice collection container in a household ice maker includes a module housing, which bears a light passage surface located at the boundary between the optoelectronic module and the space outside the module for the passage of a beam of light of the light barrier. The module further has a printed circuit board accommodated in the module housing, an optoelectronic component mounted on the printed circuit board, serving as a light transmitter or receiver, with a main lobe axis, and a cylindrical light-guiding element for guidance of the light beam located in the beam path between the light passage surface and the optoelectronic component, and at a distance from the component.

An optoelectronic module for a light barrier for fill height monitoring of an ice collection container in a household ice maker includes a module housing, which bears a light passage surface located at the boundary between the optoelectronic module and the space outside the module for the passage of a beam of light of the light barrier. The module further has a printed circuit board accommodated in the module housing, an optoelectronic component mounted on the printed circuit board, serving as a light transmitter or receiver, with a main lobe axis, and a cylindrical light-guiding element for guidance of the light beam located in the beam path between the light passage surface and the optoelectronic component, and at a distance from the component.

Provided is a refrigerator including a cabinet having a freezing compartment defined therein, an ice-maker mounted in the freezing compartment, wherein the ice-maker makes spherical ice and removes the made spherical ice downwards, an ice bin disposed below the ice-maker, and retractable and extendable in a front and rear direction, wherein the removed ice is stored in the ice bin, and a cover plate extending downward from a rear face of the ice-maker, wherein the cover plate shields a space between the ice bin and the ice-maker.

Provided is a refrigerator including a cabinet having a freezing compartment defined therein, an ice-maker mounted in the freezing compartment, wherein the ice-maker makes spherical ice and removes the made spherical ice downwards, an ice bin disposed below the ice-maker, and retractable and extendable in a front and rear direction, wherein the removed ice is stored in the ice bin, and a cover plate extending downward from a rear face of the ice-maker, wherein the cover plate shields a space between the ice bin and the ice-maker.

Solid production systems, devices, and methods utilizing oleophilic surfaces are provided in accordance with various embodiments. Some embodiments include a water tank used to store fresh water. Some embodiments include an emulsion tank that may include a set of auxiliary components that may be utilized to create and/or to pump an emulsion. This auxiliary equipment may include suction headers, ejectors, pumps, mechanical mixers, and/or hydrodynamic mixers, for example. Some embodiments include a heat exchanger that may produce a cold surface for ice formation. This surface may include an oleophilic surface that may produce an affinity for oils and/or other non-polar materials. Some embodiments include piping that may allow for the connection of the other components such that ice may be formed from a flow of water from the emulsion and the overflow may be returned to the emulsion tank. Ice making methods are also provided.

Solid production systems, devices, and methods utilizing oleophilic surfaces are provided in accordance with various embodiments. Some embodiments include a water tank used to store fresh water. Some embodiments include an emulsion tank that may include a set of auxiliary components that may be utilized to create and/or to pump an emulsion. This auxiliary equipment may include suction headers, ejectors, pumps, mechanical mixers, and/or hydrodynamic mixers, for example. Some embodiments include a heat exchanger that may produce a cold surface for ice formation. This surface may include an oleophilic surface that may produce an affinity for oils and/or other non-polar materials. Some embodiments include piping that may allow for the connection of the other components such that ice may be formed from a flow of water from the emulsion and the overflow may be returned to the emulsion tank. Ice making methods are also provided.

An icemaking appliance includes an ice storage chamber and a water jacket at least partially surrounding the ice storage chamber. A sensor assembly includes a sleeve, a conductive plug inserted into a first portion of the sleeve, and a temperature sensor inserted into a second portion of the sleeve. The first portion of the sleeve and the conductive plug are at least partially disposed within the ice storage chamber.

An icemaking appliance includes an ice storage chamber and a water jacket at least partially surrounding the ice storage chamber. A sensor assembly includes a sleeve, a conductive plug inserted into a first portion of the sleeve, and a temperature sensor inserted into a second portion of the sleeve. The first portion of the sleeve and the conductive plug are at least partially disposed within the ice storage chamber.

A refrigerator appliance, as disclosed herein, may include a cabinet, a door, a dispensing assembly, an ice-making assembly, and an ice storage bin. The door may define a dispenser recess having a transverse opening extending vertically from a top recess end to a bottom recess end and laterally from a first recess side to a second recess side. The dispensing assembly may be positioned within the dispenser recess and define an ice delivery passage. The ice-making assembly may be attached to the cabinet. The ice storage bin may include a bin body defining a storage cavity. The bin body may be selectively mounted to the door within the dispenser recess to receive ice from the dispensing assembly. The bin body may extend vertically from the top recess end to the bottom recess end and laterally from the first recess side to the second recess side.