Bulk ice preserver

Abstract

An apparatus for preserving bulk ice that includes a compartment for drying and storing ice, and a shaft for attaching an ice drying receptacle to the drying and storage compartment is disclosed. The shaft is actuated by a motor having two directions of rotation. The motor is adapted to cause the shaft and ice drying receptacle to rotate in two directions. The action of the motor, and therefore the rotation of the shaft and the ice drying receptacle, are controlled based in part on information received from one or more sensors. The compartment also has a tray with a drain for collecting and removing waste. The tray includes a resistor for melting the remains of the drying process.

Claims

1. A bulk ice preserver comprising: an ice making device configured to produce ice cubes; an ice drying and storage compartment coupled to the ice making device through a joining duct and configured to receive a plurality of ice cubes from the ice making device, the ice drying and storage compartment comprising a first drain and housing: an ice drying receptacle, a waste collection tray with a second drain, and a storage portion, the ice drying receptacle comprising an opening and configured to: receive, via the opening, a first plurality of ice cubes received from the ice making device, rotate in first and second directions to cause the first plurality of ice cubes to turn over one another in a timed manner until the ice making device sends a signal to an automaton indicating that a new ice-making cycle has been created; rotate to a selected position that causes the first plurality of ice cubes to fall out of the ice drying receptacle via the opening into the storage portion; a fastening shaft configured to fasten the ice drying receptacle to an interior wall of the drying and storage compartment; a first sensor configured to detect a position of the ice drying receptacle; the storage portion configured to hold the plurality of ice cubes that have fallen from the ice drying receptacle; a waste collection tray comprising a resistor and a second drain, the waste collection tray configured to collect water and pieces of ice generated by the ice drying process of the ice drying receptacle and water discharged by the ice making device, the resistor configured to melt the pieces of ice, the second drain configured to remove the water from the waste collection tray; ice discharge doors configured to allow removal of ice cubes from the storage compartment; and a second sensor configured to detect a quantity of ice stored in the storage compartment and to send signals to the ice making device based on a volume of the ice cubes present in the storage compartment; and a motor having two directions of rotation, the motor being coupled to the fastening shaft and configured to cause the fastening shaft and the ice drying receptacle to rotate in the two directions, wherein the ice drying receptacle is a closed drum having a rotation axis going longitudinally through said closed drum, said rotation axis coinciding with the longitudinal axis of the fastening shaft.

2. The bulk ice preserver according to claim 1, wherein the ice drying receptacle is removably attached to the fastening shaft.

3. The bulk ice preserver according to claim 1, wherein the ice drying receptacle has a door configured to cover the opening.

Description

BRIEF DESCRIPTION OF THE FIGURES

(1) What follows is a very brief description of drawings that help to better understand the invention and which is presented as a non-limiting example thereof.

(2) FIG. 1 shows an elevation view of the bulk ice preserver, wherein a series of references corresponding to the elements indicated below are provided in a non-limiting manner: 1. Ice maker. 2. Joining duct that joins the ice maker to the ice drying and storage compartment. 3. Ice drying and storage compartment. 4. Fastening structure that fastens the ice drying receptacle to the drying and storage compartment. 5. Ice drying receptacle. 6. Motor with double direction of rotation. 7. Sensor or end of travel. 8. Drying process waste collection tray. 9. Resistor. 10. Sensor or photocell. 11. Cold unit of the ice drying and storage compartment. 12. Ice drying and storage compartment doors. 13. Bulk ice preserver operation indicators. 14. Ice storage. 15. Automaton or similar. 16. Drains. 17. Ice drying receptacle door.

(3) FIG. 2 shows a cross-sectional view of the bulk ice preserver.

(4) FIG. 3 shows a perspective view of the bulk ice preserver.

DESCRIPTION OF A PREFERRED EMBODIMENT

(5) FIG. 1 shows an ice maker (1) which can make ice in any format and shape. The ice drying and storage compartment (3) is disposed underneath the ice maker. In those case where the ice maker (1) is not integrated in the bulk ice preserver, they will be joined by the ice discharge duct (2), wherein this duct (2) may have different shapes and sizes to transport the different ice formats produced by ice makers (1) to the drying and storage compartment (3).

(6) When the ice cubes enter the drying and storage compartment (3), they are directly introduced in the ice drying receptacle (5) and the ice cubes turn over one another in a timed manner in the ice drying receptacle (5) to prevent them from sticking together, until the ice maker (1) sends a signal to the automaton or similar (15), indicating that it has a new ice-making cycle. At that point, the motor (6) rotates the ice drying receptacle (5) such as to place it in the position in which ice is discharged into the storage compartment (14), whereupon all the ice cubes fall into the storage compartment (14) and the motor (6) rotates the ice drying receptacle (5) again so as to place it in the loading position so that the ice cubes made by the ice maker (1) are introduced in the ice drying receptacle (5), wherein the ice cubes turn over one another in a timed manner due to the timed activation of the motor (6) to prevent the ice cubes from sticking together when they freeze inside the drying receptacle (5). This entire process is automatically repeated until the sensor or photocell (10) detects the presence of ice, due to which it sends the automaton (15) a signal to stop the production of the ice maker (1), because the storage area (14) of the drying and storage compartment (3) is full. When the operator removes the ice from the storage section (14) and releases the sensor signal (10), the ice maker resumes the production of ice and the entire foregoing process is repeated.