A system for manufacturing clear ice products is provided. The system includes a freezing module, a demolding module, and a converting station. The freezing module includes a frame comprising a plurality of levels, a plate freezer provided at each level, and at least one mold provided for placement on each plate freezer and suitable for receiving water. A control frame is provided associated with each plate freezer and is movable from an elevated position to fill position. In the fill position, the control frame is at least partially disposed within the mold. One or more circulation pumps are associated with each control frame for circulating water in the mold to release air bubbles as the water freezes. The demolding module removes the mold from the freezing module and removes formed ice from the mold. The converting station converts the formed ice into a clear ice product.

An intelligent ice supply device and an apparatus with the intelligent ice supply device. The intelligent ice supply device includes an ice storage container, an agitating bar, a plurality of agitating plates, a plurality of ice partitions and a driving device. The agitating bar is rotatably located in the ice storage container. The agitating plates are horizontally connected to the agitating bar and located between an upper and a lower side portion of the agitating bar. The ice partitions are vertically connected to the lower side portions of the agitating bars. The driving device is connected to the upper side portion of the agitating bar and can be used to drive the agitating bar, the agitating plates and the ice partitions to automatically supply ice cubes, and the driving device can also drive the agitating bar, the agitating plates and the ice partitions to automatically eliminate ice jamming

An intelligent ice supply device and an apparatus with the intelligent ice supply device. The intelligent ice supply device includes an ice storage container, an agitating bar, a plurality of agitating plates, a plurality of ice partitions and a driving device. The agitating bar is rotatably located in the ice storage container. The agitating plates are horizontally connected to the agitating bar and located between an upper and a lower side portion of the agitating bar. The ice partitions are vertically connected to the lower side portions of the agitating bars. The driving device is connected to the upper side portion of the agitating bar and can be used to drive the agitating bar, the agitating plates and the ice partitions to automatically supply ice cubes, and the driving device can also drive the agitating bar, the agitating plates and the ice partitions to automatically eliminate ice jamming

A system for manufacturing clear ice products is provided. The system includes a freezing module, a demolding module, and a converting station. The freezing module includes a frame comprising a plurality of levels, a plate freezer provided at each level, and at least one mold provided for placement on each plate freezer and suitable for receiving water. A control frame is provided associated with each plate freezer and is movable from an elevated position to fill position. In the fill position, the control frame is at least partially disposed within the mold. One or more circulation pumps are associated with each control frame for circulating water in the mold to release air bubbles as the water freezes. The demolding module removes the mold from the freezing module and removes formed ice from the mold. The converting station converts the formed ice into a clear ice product.

A system for manufacturing clear ice products is provided. The system includes a freezing module, a demolding module, and a converting station. The freezing module includes a frame comprising a plurality of levels, a plate freezer provided at each level, and at least one mold provided for placement on each plate freezer and suitable for receiving water. A control frame is provided associated with each plate freezer and is movable from an elevated position to fill position. In the fill position, the control frame is at least partially disposed within the mold. One or more circulation pumps are associated with each control frame for circulating water in the mold to release air bubbles as the water freezes. The demolding module removes the mold from the freezing module and removes formed ice from the mold. The converting station converts the formed ice into a clear ice product.

An ice-shaping device includes a base having an inside surface and an outside surface. The inside surface defines a first ice molding cavity while the outside surface defines a channel. The ice-shaping device includes a cover having an inside surface and an outside surface. The inside surface defines a second ice molding cavity that cooperates with the first ice molding cavity. The cover includes a protrusion on the inside surface that cooperates with the channel. The cover is movable with respect to the base. When in a closed position, the base is located within an interior space of the cover defined by the inside surface of the cover. As the cover is moved from an open position to the closed position, the protrusion cooperates with the channel providing a physical interference to inhibit rotation of the cover with respect to the base.

An ice-shaping device includes a base having an inside surface and an outside surface. The inside surface defines a first ice molding cavity while the outside surface defines a channel. The ice-shaping device includes a cover having an inside surface and an outside surface. The inside surface defines a second ice molding cavity that cooperates with the first ice molding cavity. The cover includes a protrusion on the inside surface that cooperates with the channel. The cover is movable with respect to the base. When in a closed position, the base is located within an interior space of the cover defined by the inside surface of the cover. As the cover is moved from an open position to the closed position, the protrusion cooperates with the channel providing a physical interference to inhibit rotation of the cover with respect to the base.

An electric ice press includes a mold body having a first mold segment and a second mold segment movable relative to each other. A heated guide rail extends between the first mold segment and the second mold segment to transfer heat from the first mold segment to the second mold segment. The heated guide rail may be a heat pipe for transferring heat generated by a base heater in the first mold segment or an electrical resistance heating rod for generating heat, either of which requires only a single power cord electrically coupled to only the first mold segment.

An electric ice press includes a mold body having a first mold segment and a second mold segment movable relative to each other. A heated guide rail extends between the first mold segment and the second mold segment to transfer heat from the first mold segment to the second mold segment. The heated guide rail may be a heat pipe for transferring heat generated by a base heater in the first mold segment or an electrical resistance heating rod for generating heat, either of which requires only a single power cord electrically coupled to only the first mold segment.

Methods and devices are described for shaping ingots of ice. Devices may include a support structure, a mold for shaping ice ingots, the mold being mounted to the support structure. The devices may also include a first upper platen assembly disposed above a first lower platen assembly, a first positioning means, and at least one liquid inlet valve for each of the first upper platen assembly and the first lower platen assembly.