The present invention relates to the creation of clear ice spheres. Standard ice cubes are opaque and melt quickly in beverages resulting in a warm drink with a watered down taste. Clear ice spheres can ameliorate both problems. Crystal clear ice making devices available today produce clear ice primarily using one of three methods, each with their own drawbacks:
The first method freezes water layer by layer either by spraying water layers as with U.S. Pat. No. 6,857,277 or by slowly adding small amounts of water as with U.S. Pat. No. 6,935,124. The layers of water are too thin to trap impurities and gasses as they freeze and each layer of clear ice builds on the one before it to create a clear ice shape. Unfortunately, this process requires expensive, specialized equipment and machinery; further, the product available to most consumers is integrated into high-end refrigerators and only makes ice cubes.
The second method agitates the water as it freezes, typically by circulating the water as with U.S. Pat. No. 5,884,490. This approach keeps gasses from dissolving in the solution and prevents formation of the outer shell of ice that traps gasses in the ice as it freezes. As with the first method, agitation requires expensive, complex equipment to agitate the water with either a gas or mechanical device. Its primary application is with large ice sculpture molds, but it is neither practical nor economical for small consumer products such as clear ice spheres.
The third method freezes water from the inside out using “refrigerated supports” as with U.S. Pat. No. 5,297,394. This approach pushes oxygen and impurities out into the unfrozen water as it freezes outwards from the supports. The method allows commercial entities to produce large quantities of ice, but once again it requires expensive equipment and refrigeration technology; furthermore, the method can only produce hollow cylindrical tubes of ice (commonly seen in bags of ice “cubes” at convenience stores and supermarkets). These hollow tubes melt very quickly diluting any beverage they cool, unlike ice spheres.
Each of the existing means of producing clear ice requires costly, complicated, machinery to produce clear ice and in some cases cannot produce ice spheres at all. The products on the market designed for consumer use do not fare much better. Simple rubber ice ball molds allow ice to freeze from the outside in on all sides trapping impurities and gases and producing a cloudy product (albeit at low cost). Aluminum or copper ice presses stamp out clear ice balls, but require the consumer to purchase blocks of clear ice from a commercial vendor or other source (all at exorbitant cost). There are even vendors who will deliver clear ice spheres in freezer packs for a hefty cost.
None of the consumer-level ice sphere products on the market today produce their own clear ice and the existing methods of producing clear ice are too costly and complicated for consumer-level application. There is a need for a device that produces crystal clear ice spheres easily and cost effectively.
In accordance with one exemplary embodiment a device for producing clear ice spheres comprises a plurality of releasably connected molds and an insulated vessel.
11 Large half mold
12 Large half mold fill hole
13 Large half mold semi-spherical cavity
14 Large half mold exit hole
15 Outer flange
16 Cap
17 DELETED
18 Overflow cavity
30 Small half mold
31 Small half mold fill hole
32 Inner flange
33 Small half mold exit hole
34 Small half mold semi-spherical cavity
35 DELETED
50 Cup
51 Cup cavity
52 DELETED
60 Cup exit hole
70 Insulated Vessel
71 Vessel cavity
72 DELETED
The following detailed description is of the best currently contemplated modes of carrying out exemplary embodiments of the invention. The description is not to be taken in a limiting sense, but is made merely for the purpose of illustrating the general principles of the invention, since the scope of the invention is best defined by the appended claims. Broadly, an embodiment of the present invention provides a device and method for producing clear ice shapes that may include two half molds that fit together; a cup with a cavity wherein two half molds may be placed inside of the cavity; and an insulated vessel wherein the cup and half molds may be placed inside the upper portion of the insulated vessel leaving a hollow space in the lower portion.
One exemplary embodiment of the large half mold 11 is illustrated in
Cup 50 is illustrated in
Operation of the device requires assembly of the device, filling and freezing a liquid in the device, and finally extraction of the clear ice ball.
Assembly of the device is illustrated in
With the device assembled it can be filled with liquid, typically water, but any liquid that will freeze at normal freezer temperatures (e.g. 0 degrees Fahrenheit) may be used. The liquid may be slowly poured into large half mold fill hole 12 until it rises above the hole and into overflow cavity 18. The filled vessel may be shaken, tapped or otherwise agitated to release trapped air; additional liquid may need to be added if the liquid level drops below large half mold fill hole 12 after any air is released. Once filled the device is submitted to temperatures below the freezing point of the liquid. Insulated vessel 70 prevents the liquid from freezing on all sides which would trap gases and impurities. Only the top of the device is unprotected from the freezing temperatures thus the liquid freezes from the top down with liquid at the bottom of insulated vessel 70 freezing last. This forces gases and impurities down out of the spherical cavity through the exit holes and into the unfrozen liquid leaving a crystal clear ice sphere in the spherical cavity and a mass of cloudy ice in the lower section of insulated vessel cavity 71.
Once the liquid in the spherical mold cavity is frozen the clear ice sphere may be removed. First the two half molds and cup 50 are removed. This is accomplished by either lifting the assembly out of insulated vessel 70 by cap 16 or by rotating cap 16 while keeping insulated vessel 70 fixed to break cup 50 free from ice formed in the lower section of insulated vessel 70. Warm liquid may be used to expedite or ease this extraction. Next the two half molds may be removed from cup 50 by either lifting them out by cap 16 or by again rotating cap 16 while fixing cup 50 to break the half molds free from any ice formed between cup 50 and the two half molds. Again warm liquid may be used to expedite or ease this extraction. Lastly small half mold 30 is removed from large half mold 11 by pulling small half mold 30 away starting from large half mold 11 at small half mold exit hole 33. Again warm liquid may be used to expedite or ease this extraction. The clear ice sphere may now be removed from the device.
One exemplary additional embodiment removes cup 50 from the device and modifies the shape of insulated vessel cavity 71 to conform to the shape of the two half molds mated together (a cylinder in the exemplary embodiment illustrated in
Other embodiments of small half mold 30 and large half mold 11, which are oriented vertically when mated in the exemplary embodiment illustrated in
Accordingly the reader will see that the exemplary embodiments can create clear ice using a top down freezing method and can produce clear ice spheres, all without complex or expensive equipment.
Although the description above contains many specificities, these should not be construed as limiting the scope of the embodiments, but as merely providing illustrations of some of several embodiments. For example, cap 16 may have a different shape such as square, triangle, etc.; the half molds may mate vertically, horizontally, or at some angle in between; cup 50 may be removed, etc.
Thus the scope of the embodiments should be determined by the appended claims and their legal equivalents, rather than by the examples given.
This application claims the benefit of provisional patent application No. 61857608 filed 2013 Jul. 23 by the present inventors.
Number | Date | Country | |
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61857608 | Jul 2013 | US |