An ice maker includes an ice making unit and an ice storage bin. A frame is positioned between the ice making unit and the storage bin. An ice making tray is coupled with the frame, including a base defining a first plurality of apertures and a second plurality of apertures. A plurality of ice forming features is positioned proximate the first plurality of apertures. The ice forming features are coupled to and extend away from the base. A heating element is in thermal communication with the ice forming features. A wastewater disposal assembly is coupled with the ice making tray.

An ice maker includes an ice making unit and an ice storage bin. A frame is positioned between the ice making unit and the storage bin. An ice making tray is coupled with the frame, including a base defining a first plurality of apertures and a second plurality of apertures. A plurality of ice forming features is positioned proximate the first plurality of apertures. The ice forming features are coupled to and extend away from the base. A heating element is in thermal communication with the ice forming features. A wastewater disposal assembly is coupled with the ice making tray.

An ice bath comprising a container, a refrigeration coil for causing liquid in the container to turn to ice, a pipe for carrying liquid to be cooled by the ice bath for dispense and a plurality of conductive probes for measuring ice thickness, wherein the conductive probes are provided between at least part of the refrigeration coil and the pipe for carrying liquid to be dispensed such that a first one of the conductive probes is provided closer to the refrigeration coil at least two other conductive probes, and thereby the at least two other conductive probes are provided closer to the piping than the first conductive probe, and wherein the second and third probes are equidistant from the refrigeration coil, the ice bath further comprising means for measuring the conductance between the first probe and the second probe, the first probe and the third probe, and the second probe and the third probe.

An ice bath comprising a container, a refrigeration coil for causing liquid in the container to turn to ice, a pipe for carrying liquid to be cooled by the ice bath for dispense and a plurality of conductive probes for measuring ice thickness, wherein the conductive probes are provided between at least part of the refrigeration coil and the pipe for carrying liquid to be dispensed such that a first one of the conductive probes is provided closer to the refrigeration coil at least two other conductive probes, and thereby the at least two other conductive probes are provided closer to the piping than the first conductive probe, and wherein the second and third probes are equidistant from the refrigeration coil, the ice bath further comprising means for measuring the conductance between the first probe and the second probe, the first probe and the third probe, and the second probe and the third probe.

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.

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.

The present application relates to the field of ice making, and provides an ice making system and a refrigeration apparatus. The ice making system includes an ice making assembly, a water collecting tank located below the ice making assembly, and a water diversion ice rake structure. The water diversion ice rake structure includes: a pair of water receiving lateral wings, each of which is constructed with a rotary end and a free end; the pair of water receiving lateral wings are rotatably disposed on opposite sides of the ice making assembly through the respective rotary ends to rotate between an ice making position and an ice falling position. At the ice making position, the free ends of the pair of water receiving lateral wings are butted in a space between the ice making assembly and the water collecting tank to form a closure space with an opening facing the ice making assembly, and a water outlet communicating with the water collecting tank is constructed on one side of the closure space. The present application may solve the problems of condensed water dripping out and water splashing outward during ice making.

The present application relates to the field of ice making, and provides an ice making system and a refrigeration apparatus. The ice making system includes an ice making assembly, a water collecting tank located below the ice making assembly, and a water diversion ice rake structure. The water diversion ice rake structure includes: a pair of water receiving lateral wings, each of which is constructed with a rotary end and a free end; the pair of water receiving lateral wings are rotatably disposed on opposite sides of the ice making assembly through the respective rotary ends to rotate between an ice making position and an ice falling position. At the ice making position, the free ends of the pair of water receiving lateral wings are butted in a space between the ice making assembly and the water collecting tank to form a closure space with an opening facing the ice making assembly, and a water outlet communicating with the water collecting tank is constructed on one side of the closure space. The present application may solve the problems of condensed water dripping out and water splashing outward during ice making.

This ice making machine includes an ice making unit that includes an ice making surface and a cryogen flow channel through which a cryogen for cooling the ice making surface flows; a pump that pressurizes and discharges the cryogen cooled by a heat exchanger; and a control unit that controls a discharge amount of the pump. The cryogen is carbon dioxide, and the control unit controls the pump such that the cryogen is in a gas-liquid mixed state at an outlet of the cryogen flow channel.