The present disclosure relates generally to a refrigerator appliance and to an automatic ice-sphere-making system for the refrigerator appliance. More particularly, the present disclosure relates to an automatic spherical ice maker that can be fixed in the refrigerator appliance or used in place of a conventional ice cube maker.
Moreover, the automatic spherical ice maker can be positioned for example in a freezer compartment of the refrigerator appliance or in a dedicated ice making compartment located within a fresh food compartment of the refrigerator appliance.
In general, clear spherical ice pieces have become popular and are used in bourbon, scotch, whiskey, craft cocktails, soft drinks, and other drinks. The clear spherical ice piece is desirable for use in such drinks because of its slow melting rate, large surface area, and attractive visual appearance.
The standard practice currently used to produce spherical ice pieces is to use a manual process which relies on an insulated mold that is manually filled with water, placed in the freezer compartment by the user/consumer, and then when the water is frozen the spherical ice pieces are manually harvested by the user/consumer. However, the insulated mold requires a significant amount of time to freeze the water, thus allowing dissolved solids to precipitate and allow for degasification of the water. While the manual process is adequate to produce spherical ice pieces, it is extremely slow and requires manual input from the user/consumer.
An ice-ball press is also known which is manually filled with ice and then the press forms a single sphere of ice with the help of gravity. Again, the ice-ball press is both time consuming and inefficient.
However, there is currently no home refrigerator appliance on the market with an installed automatic ice maker that is capable of producing clear spherical ice pieces.
An apparatus consistent with the present disclosure is directed to providing an automatic spherical ice maker that can be fixed in a refrigerator appliance or interchanged with and replace an existing ice cube maker in the refrigerator appliance.
An apparatus consistent with the present disclosure is directed to providing an automatic spherical ice maker that can be positioned for example in a freezer compartment of the refrigerator appliance or in a dedicated ice making compartment located within a fresh food compartment of the refrigerator appliance.
According to one aspect, the present disclosure provides a refrigerator comprising: an ice compartment region disposed in at least one of a fresh food compartment or a freezer compartment; and an automatic spherical ice maker disposed in the ice compartment region, the automatic spherical ice maker including an upper stationary ice mold having at least one ice cavity with a hemispherical shape, and a lower rotatable ice mold having at least one ice cavity with a hemispherical shape and corresponding to the ice cavity of the upper stationary ice mold, so that together the at least one ice cavity of the upper stationary ice mold and the at least one cavity of the lower rotatable ice mold form at least one spherical mold which is configured to produce at least one substantially spherical ice ball at a time, wherein the upper stationary ice mold has a first heating element and the lower rotatable ice mold has a second heating element, thereby to facilitate release of the at least one spherical ice ball from the at least one spherical mold.
According to another aspect, the upper stationary ice mold has two ice cavities each with a hemispherical shape, and the lower rotatable ice mold has two ice cavities each with a hemispherical shape and respectively corresponding to the two ice cavities of the upper stationary mold, so that together the two ice cavities of the upper stationary ice mold and the two ice cavities of the lower rotatable ice mold form two spherical molds which are configured to produce two substantially spherical ice balls at a time.
According to another aspect, the at least one spherical ice ball has a diameter of approximately 2.5 inches.
According to another aspect, the lower rotatable ice mold is fixedly mounted to a driven shaft via two spaced-apart extension arms.
According to another aspect, the driven shaft includes a driven gear which is coupled to a drive shaft via a drive gear, and the drive shaft is coupled to a drive motor.
According to another aspect, the drive motor comprises one of a DC motor or a stepper motor.
According to another aspect, the lower rotatable ice mold has an upper flange portion that surrounds the two ice cavities, and wherein the upper flange portion is formed with a groove for receiving a seal member for providing a seal between the upper stationary ice mold and the lower rotatable ice mold on condition that the lower rotatable ice mold is in a closed position to form the two spherical molds.
According to another aspect, the two ice cavities of the upper stationary ice mold are mounted on and extend below a mold support plate.
According to another aspect, an upper surface of the mold support plate has a generally U-shaped recess or groove for receiving the first heating element.
According to another aspect, the mold support plate has a pair of air-vent-filler tubes disposed in respective openings formed in an upper surface of the mold support plate.
According to another aspect, each one of the pair of air-vent-filler tubes includes a plurality of outer cutouts formed in a flange portion that is disposed in a corresponding one of the openings formed in the upper surface of the mold support plate.
According to another aspect, the automatic spherical ice maker is configured to be either fixed in the ice compartment region of the refrigerator, or interchanged with and replace an existing ice cube maker in the ice compartment region of the refrigerator appliance.
According to another aspect, the present disclosure provides an automatic spherical ice maker automatic spherical ice maker for a refrigerator appliance, comprising: an upper stationary ice mold having at least one ice cavity with a hemispherical shape, and a lower rotatable ice mold having at least one ice cavity with a hemispherical shape and corresponding to the ice cavity of the upper stationary ice mold, so that together the at least one ice cavity of the upper stationary ice mold and the at least one cavity of the lower rotatable ice mold form at least one spherical mold which is configured to produce at least one substantially spherical ice ball at a time, wherein the upper stationary ice mold has a first heating element and the lower rotatable ice mold has a second heating element, thereby to facilitate release of the at least one spherical ice ball from the at least one spherical mold.
According to another aspect, the upper stationary ice mold has two ice cavities each with a hemispherical shape, and the lower rotatable ice mold has two ice cavities each with a hemispherical shape and respectively corresponding to the two ice cavities of the upper stationary mold, so that together the two ice cavities of the upper stationary ice mold and the two ice cavities of the lower rotatable ice mold form two spherical molds which are configured to produce two substantially spherical ice balls at a time.
According to another aspect, the at least one spherical ice ball has a diameter of approximately 2.5 inches.
According to another aspect, the lower rotatable ice mold is fixedly mounted to a driven shaft via two spaced-apart extension arms.
According to another aspect, the driven shaft includes a driven gear which is coupled to a drive shaft via a drive gear, and the drive shaft is coupled to a drive motor.
According to another aspect, the drive motor comprises one of a DC motor or a stepper motor.
According to another aspect, the lower rotatable ice mold has an upper flange portion that surrounds the two ice cavities, and wherein the upper flange portion is formed with a groove for receiving a seal member for providing a seal between the upper stationary ice mold and the lower rotatable ice mold on condition that the lower rotatable ice mold is in a closed position to form the two spherical molds.
According to another aspect, the two ice cavities of the upper stationary ice mold are mounted on and extend below a mold support plate.
According to another aspect, an upper surface of the mold support plate has a generally U-shaped recess or groove for receiving the first heating element.
According to another aspect, the mold support plate has a pair of air-vent-filler tubes disposed in respective openings formed in an upper surface of the mold support plate.
According to another aspect, each one of the pair of air-vent-filler tubes includes a plurality of outer cutouts formed in a flange portion that is disposed in a corresponding one of the openings formed in the upper surface of the mold support plate.
According to another aspect, the present disclosure provides an automatic spherical ice maker for a refrigerator appliance, comprising: an upper stationary ice mold having at least one ice cavity with a hemispherical shape, and a lower rotatable ice mold having at least one ice cavity with a hemispherical shape and corresponding to the ice cavity of the upper stationary ice mold, so that together the at least one ice cavity of the upper stationary ice mold and the at least one cavity of the lower rotatable ice mold form at least one spherical mold which is configured to produce at least one substantially spherical ice ball at a time, wherein the automatic spherical ice maker is configured to be interchanged with and replace an existing ice cube maker in the refrigerator appliance.
The accompanying drawing figures incorporated in and forming a part of this specification illustrate several aspects of the invention, and together with the description serve to explain the principles of the invention.
The exemplary embodiments set forth below represent the necessary information to enable those skilled in the art to practice the invention. Upon reading the following description in light of the accompanying drawing figures, those skilled in the art will understand the concepts of the invention and will recognize applications of these concepts not particularly addressed herein. It should be understood that these concepts and applications fall within the scope of the disclosure and the accompanying claims.
Moreover, it should be understood that terms such as top, bottom, front, rear, upper, lower, and the like used herein are for orientation purposes with respect to the drawings when describing the exemplary embodiments and should not limit the present invention. Also, terms such as substantially, approximately, and about are intended to allow for variances to account for manufacturing tolerances, measurement tolerances, or variations from ideal values that would be accepted by those skilled in the art.
An ice bucket 21 is provided underneath the automatic spherical ice maker 18. Although the term ice bucket is used, ice bin, ice storage container, and the like are alternative terms for describing the ice bucket 21. The ice bucket 21 is shown as a removable ice bucket for storing ice, the removable ice bucket being removably disposed in the ice compartment region 14. The ice bucket 21 has a front portion 22 with a grip 23 for a user to grasp with their fingers to pull and slide the ice bucket 21 out of the ice compartment region 14 to access the spherical ice balls or empty the spherical ice balls from the ice bucket 21. The ice bucket 21 rests on the L-shaped floor portion 15 when it is inserted into the ice compartment region 14. The ice bucket 21 may have a raised side wall portion 24 and raised rear wall portion 25 to help retain the ice pieces as they fall into the ice bucket 21 from the automatic spherical ice maker 18 during harvest and during storage as the level of the ice pieces increases in the ice bucket 21. A level detection device such as a bail arm (not shown) is configured to turn the automatic spherical ice maker 18 on when the level of the spherical ice balls has gone below a preset level as the user removes the spherical ice balls from the ice bucket 21 for use, as well as turn off the automatic spherical ice maker 18 when the spherical ice balls have reached a preset full level in the ice bucket 21. For example, this could be just a single layer of spherical ice balls in the ice bucket 21 in the case that the spherical ice balls are large, such as 2.5 inches in diameter. Also, other level sensing devices could be used such as optical sensors.
With reference to
In particular, the automatic spherical ice maker 18 is configured to make, for example but not limited to, 2.5 inch diameter clear, substantially spherical ice balls that are typically used in bourbon, scotch, whiskey, craft cocktails, soft drinks, and other drinks. As best shown in
With reference to
The lower rotatable ice mold 40 having two ice cavities 41 and 42 is fixedly mounted to the driven shaft 62 via two spaced-apart extension arms 65 and 66. As shown in
With reference to
As shown in
As best seen in
As best seen in
While the automatic spherical ice maker 18 is shown in
The ice compartment region 200 is disposed in an upper left hand corner of the fresh food compartment 103. The ice compartment region 200 can be located at other positions within the fresh food compartment 103.
With reference to
As shown in
Since the automatic spherical ice maker 18′ is located in the insulated housing 231 in the ice compartment region 200 within the fresh food compartment 103, it is necessary to provide cold air either via a duct (not shown) from the freezer compartment 101 or from a dedicated evaporator (not shown) for the insulated housing 231 or an evaporator cooling tube (not shown) for the automatic spherical ice maker 18′. The evaporator cooling tube may be embedded in or in contact with the upper stationary ice mold 30.
When in use, the automatic spherical ice maker 18, 18′ according to an exemplary embodiment consistent with the present disclosure produces substantially spherical ice balls IB by filling the spherical cavities of the closed spherical molds M1 and M2 with water through the air-vent-filler tubes 74 and 75 to a predetermined level and then allowing this water to freeze during the ice production mode. The thermal mass of the closed spherical molds M1 and M2 allows sufficient freezing time for the spherical ice to have a clear appearance. When the spherical ice reaches a completely frozen state, the ice harvesting mode begins by activating the first and second heating elements 72 and 72′ to slightly melt the ice that is in contact with a surface of each of the closed spherical molds M1 and M2 in order to release the two spherical ice balls IB from the spherical molds M1 and M2. The motor 50 is then activated to rotate the lower rotatable ice mold 40 down away from the upper stationary ice mold 30 to thereby open and release the two spherical ice balls IB from the spherical molds M1 and M2 into the ice storage bucket 21, 251.
An automatic spherical ice maker consistent with the present disclosure provides for the automatic generation of multiple, clear, substantially spherical ice balls at the same time. Moreover, the user/customer has the peace of mind that they always have a supply of ice balls or spheres when desired without having to wait long periods of time or having to manually form the ice balls one-by-one using an ice-ball press or in a manual insulated mold similar to a conventional ice cube tray.
The present invention has substantial opportunity for variation without departing from the spirit or scope of the present invention. For example, the automatic spherical ice maker may be configured to make smaller clear, substantially spherical ice balls, such as but not limited to, 2.0 inch, 1.5 inch, 1.0 inch, etc., diameter ice balls. Also, instead of the sole ice maker or a replacement ice maker, the automatic spherical ice maker could be added as an additional ice maker to the traditional ice maker, especially in high end refrigerator units that are dedicated to use in home bars such as in entertainment rooms and the like. Still further, while
Those skilled in the art will recognize improvements and modifications to the exemplary embodiments of the present invention. All such improvements and modifications are considered within the scope of the concepts disclosed herein and the claims that follow.