This invention relates to temperature-insulating containers and provides a thermal-transfer container sleeve for warming, cooling, or maintaining the temperature of a fluid inside a thermally-conductive container.
Many substances, including fluids and gels, have a temperature or range of temperature for optimum use. Some beverages are meant to be consumed hot or warm, while others are meant to be consumed cold. Additionally, certain fluid products may be more effective at a certain temperature, and some fluid products may only be used safely at a specified temperature. For example, some fluids, such as blood, must be kept cold during storage, transfer, and handling, but then must be brought up to a warmer temperature just before use in a transfusion. In such a case, the usual method available to health-care providers is to warm the fluid in a microwave oven. However, an ambulance or medic in the field may not have such a microwave oven available. Similarly, a beverage purchased in a can or bottle, at a location away from the home or office, might not be at the temperature that a customer desires, and the customer would want to make it warmer or cooler in a quick and portable way. When cold beverages are consumed in warm or hot environments, the beverage tends to warm up, and when hot beverages are consumed in cold environments or consumed slowly, the beverage tends to cool off.
Although a thermally insulated beverage container might be useful, many times beverages are not sold in insulated containers, and some venues do not allow any outside beverages or beverage containers to be brought into the venue. Further, an insulated container cannot actively put heat into, or draw heat out of, the contained fluid. Although there are portable ways to heat and cool fluids using electricity or fuel, such as butane, devices having electrical components or fuel storage might not be allowed, or might otherwise be undesirable or unsafe, in some locations and circumstances.
Several inventors have attempted to provide various solutions to transferring heat in relation to a canned or bottled drink.
For example, U.S. Pat. No. 8,056,757 was issued to assignee King Fand University of Petroleum and Minerals on Nov. 15, 2011, covering a “Hot Beverage Cup Sleeve.” The concept, invented by Rached Ben Mansour and Muhammad A. Hawwa, discloses a hot beverage cup and a sleeve that bring together two modes of heat transfer, conduction and radiation. The sleeve has an inner face with a plurality of high reflectivity surfaces for radiating heat back to the cup. The sleeve also has a plurality of insulating members for containing insulating air. Each of the insulating members is positioned to space the high reflectivity surfaces away from the cup. A low emissivity film can be adhered to the cup without touching the insulating members. The film can also be attached to the sleeve facing but spaced from the high reflectivity surfaces. This cup and sleeve arrangements minimize thermal contact and reduce heat transfer. Thus, the hot beverage cup and sleeve protect a person's hand as well as extend the time of keeping the beverage hot.
U.S. Publication No. 2011/0192859, published by inventor Rita Belford on Aug. 11, 2011, discloses a “Beverage Container Sleeve and Method of Making and Using Same.” Per the disclosure of this Belford publication, an improved cooling and/or heating system for a beverage container, a method of manufacturing the container sleeve, and a method of using the container sleeve are provided. The improved container sleeve is configured to cover a beverage container and actively cool and/or heat the container while helping to maintain the temperature of the beverage once it is cooled or heated. The cover includes a flexible insulating material with a cooling and/or heating device positioned on the inner surface.
U.S. Pat. No. 4,388,813, issued on Jun. 21, 1983 to assignee Aurora Design Associates, Inc., covers a “Server for Wine Bottles and the Like” The product, as shown below, was conceived by inventors James H. Gardner and Noel H. de Nevers and discloses a server for chilled wine and similar beverages or foods includes a generally cylindrically-shaped side wall into which a bottle or other container may be placed. The side wall is constructed of a heat conductive material such as aluminum, copper, alloys thereof, and so forth, of sufficient thickness to conduct heat as needed in its circumferential direction. The server also includes an ice receptacle formed to surround a side portion of the side wall to hold ice in contact with the side wall. The side wall acts to present the wine container with a surface which is at or below the temperature of the wine. This substantially eliminates the transfer of heat by radiation to the wine container. The server also minimizes conductive and/or convective heat transfer between the wine bottle and the surroundings.
International Publication No. 2007/099114 was published by Arcelik Anonim Sirketi on Sep. 7, 2007, discloses a cooling device characterized by a can holder situated in such cooling device, and can be produced with ease as a result of a shaping process implemented on both sides of a thin sheet and presents a cost advantage by making use of a small amount of material. More specifically, it is produced by bending and warping a metal sheet or shaping plastic by means of a mold in a wavy or sinusoidal shape. It has one or more containers with a can disposed in each one, arranged on both the front and back sides of the sheet, the consecutive ones being arranged on different sides of the sheet.
U.S. Pat. No. 4,870,837 was issued on Oct. 3, 1989 to inventor Janine J. Weins, covering a “Device for Maintaining the Chill on a Bottle of Wine.” The disclosed invention is directed to a vessel having a high heat capacity sidewall for use in maintaining the chill on a container such as a bottle of wine. The base of the vessel may be provided with an insulating layer to limit heat conductivity between the vessel and a surface on which the vessel may be placed. In a preferred embodiment of the present invention, the vessel is provided with a closure means. In another preferred embodiment the vessel is provided with an absorbent layer so that when the container is removed from the vessel it will be wiped of condensed moisture. In yet another embodiment of the present invention, the vessel is provided with high heat capacity fins to increase the thermal conductivity between a container placed within the vessel and the vessel sidewall. The fins may further serve to constrict the movement of a container placed within the vessel. In a preferred embodiment, the sidewall of the vessel contains a fluid having a melting point near the temperature at which it is desired to maintain the container which may be placed within the vessel. If the container is used to store white wine, the sidewall of the vessel may be filled with a fluid having melting point of about 0° C. to 7° C. If the vessel is used to store red wine, the sidewall may be filled with a fluid having a melting point of between about 15° C. and 22° C. The disclosed invention is compact and stable, is less bulky than ice buckets, and does not rely on ice and water to maintain the chill on a container.
U.S. Pat. No. 4,871,597, issued on Oct. 3, 1989 to inventor Michael A. Hobson, covers a “Light-Weight Multi-Layer Insulating Enclosure.” This '597 patent specially covers a light-weight multi-layer insulating enclosure comprised of four different layers of materials to provide maximum insulation for containers ranging from relatively rigid to relatively flexible construction. The improved insulating qualities of the present invention are achieved through the use of an inner-most fabric liner layer, a second inner-most insulating layer which includes a polymeric foam, a third inner-most metalized polymer film reflective layer, and an outer-most fabric mesh layer. The enclosure is light-weight, collapsible and removable.
U.S. Pat. No. 3,603,106, as issued on Sep. 7, 1971 to inventors John W. Ryan and Wallace H. Shapero, for a “Thermodynamic Container” relates to a food and beverage container, and more particularly to a container of the thermodynamic type capable of regulating the temperature of the food and beverage therein. The thermodynamic container comprises an outer wall of low thermal conductivity separated by an insulating material from an inner metal capsule of very high thermal conductivity having a heat-storage material disposed therein. Beverages too hot to drink melt the heat-storage material which in turn cools the beverage to a drinkable temperature within two minutes. Heat lost during the beverage's cooling is then returned to the beverage to maintain it at a drinkable temperature as the heat-storage material re-solidifies.
While the examples described above may be satisfactory in some circumstances, there remains a need for a thermal-transfer method that is portable, is not itself a fluid container, and can be prepared for use by pre-heating or pre-cooling with equipment available in a standard home or office kitchen.
This invention provides a thermal-transfer container sleeve system and method for warming, cooling, or maintaining the temperature of a fluid inside a thermally-conductive container. The thermal-transfer container sleeve is portable, is non-electric and non-fuel-burning, and is not itself a fluid container, which might not be allowed in some places or circumstances. The thermal-transfer container sleeve is easily pre-heated or pre-cooled with standard kitchen equipment. The thermal-transfer container sleeve provides high-thermal-capacitance units attached to the inside of an insulation sleeve in a way that maximizes thermal contact with the thermally-conductive container, but provides additional surface area when not mounted upon a thermally-conductive container to increase the efficiency of pre-heating or pre-cooling.
Reference will now be made to the drawings, wherein like parts are designated by like numerals, and wherein:
Referring to
The thermal-transfer container sleeve system 10 provides an insulating sleeve 1 of sheet material such as neoprene, silicone, or similar rubbers or plastics. The sheet material is insulating, to prevent or lessen thermal transfer to the outside environment. Silicone can be made extremely heat-resistant, and accordingly may be a preferred choice for uses involving pre-heating of the thermal-transfer container sleeve system 10 to a high temperature. In use, the insulating sleeve 1 has an inside face or surface, toward the fluid container, and an outside face or surface.
On the inside of the insulating sleeve are arrayed several high-thermal-capacitance units 2, which, in use, will be in thermal contact with the fluid container. The high-thermal-capacitance units are adapted to transfer thermal energy with an outside heat source or conventional sink. The high-thermal-capacitance units 2 are made from material having a high thermal capacitance, also called thermal mass and heat capacity. Keeping in mind that only heat is energy that can move, and becoming cold means giving up heat, a material with high thermal capacitance will take in heat, effectively store that heat for a time, and give up heat slowly. An illustrative example is a clay brick heated all day by the sun, still giving off heat long after the sun sets. Suitable high-thermal-capacitance materials for making the high-thermal-capacitance units 2 are metals, such as copper, brass, and aluminum, and ceramics, which are made from clay. These materials are light enough to be portable, are mostly affordable, excluding copper, and are not dangerous or toxic in this type of use.
In the illustrated embodiment, the high-thermal-capacitance units 2 are formed as bars and are arrayed with long dimensions lining up with the long dimension, or longitudinal axis, of the fluid container. The high-thermal-capacitance units 2 have modified “trapezoidal” cross-sections, with the face attached to the insulating sleeve being wider than the face which makes contact with the fluid container. The inner faces of the high-capacitance units 2 have an arcuate configuration complimentary to the curvature of a container, such as the curvature of a conventional bottle or a can. The outside faces of the high-capacitance units 2 have similarly curved or arcuate faces, albeit with the arc having greater radius that the arc of the inner faces. When the thermal-transfer container sleeve system 10 is wrapped around a fluid container, as shown in
The high-thermal-capacitance units 2 come into contact with each other, combining their thermal masses and minimizing any loss of thermal energy through air gaps. The physical and thermal contact among the high-thermal-capacitance units 2 promotes maintenance of an even temperature or rate of thermal transfer throughout all of the high-thermal-capacitance units 2. Therefore, the thermal-transfer container sleeve 10 applies a consistent amount of energy distributed over almost all of the container, and therefore avoids undesirable effects such as localized overheating or scorching, or localized over-cooling or freezing.
When the thermal-transfer container sleeve system 10 is laid flat or opened up, the air gaps re-appear, and become useful thermal-transfer gaps 3 to speed up the pre-heating or pre-cooling process in anticipation of the next use. An article put into a home freezer will freeze faster if cold air is allowed to circulate around the article. The thermal-transfer gaps 3 promote thermal transfer by providing greater exposed surface area, and circulation space, around the high-thermal-capacitance units 2.
The illustrated embodiment of the thermal-transfer container sleeve system 10 provides a sleeve closure 4 or closures to hold the sleeve closed against the fluid container, and to allow laying flat while pre-heating or pre-cooling. Such closures are known in the art, and can incorporate hook-and-loop tape, snaps, zippers, and magnetic closures.
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It is envisioned just as the system 10 could be used in healthcare application, it could similarly be used in domestic applications such as for example keeping a pizza or a ready-made dinner warm, or keeping items such as cold cuts, fish, meat, and the like cold during transport.
Turning now to the alternative embodiment of the present invention shown in
Each unit 42 can be formed in a variety of desired configurations, such as cubes, spheres, hollow bodies, solid bodies, and the like. The thermal units 42 can be placed in a freezer to lower their temperature. When removed from the freezer, the thermal units 42 will retain cold for a certain period of time. During that time, they can be placed in a fluid container, such as glass 40 and lower the temperature of the fluid inside the container without diluting the fluid.
It is envisioned that the thermal units 42 will be beneficial in a variety of circumstances. For instance, the thermal units 42 can be used in drinks where addition of water ice cubes would not be desirable. Since the thermal units 42 do not melt, as ice cubes would, the thermal units 42 will cool the liquid without diluting it. Two or more thermal units 42 can be secured together by a flexible connector and removed from the container 42 by lifting one of the “chain” of the thermal units 42. After use, the thermal units 42 can be washed and re-used numerous times.
Many other changes and modifications can be made in the system and method of the present invention without departing from the spirit thereof. I therefore pray that my rights to the present invention be limited only by the scope of the appended claims.
Number | Name | Date | Kind |
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2576698 | Russum | Nov 1951 | A |
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3603106 | Ryan et al. | Sep 1971 | A |
4388813 | Gardner et al. | Jun 1983 | A |
4399668 | Williamson | Aug 1983 | A |
4660594 | Gocze | Apr 1987 | A |
4870837 | Weins | Oct 1989 | A |
4871597 | Hobson | Oct 1989 | A |
4972759 | Nelson | Nov 1990 | A |
4989418 | Hewlett | Feb 1991 | A |
5322181 | Nelson | Jun 1994 | A |
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6601728 | Newkirk | Aug 2003 | B1 |
8056757 | Mansour et al. | Nov 2011 | B2 |
9700951 | Matsuzaki et al. | Jul 2017 | B2 |
20070068958 | Besser | Mar 2007 | A1 |
20100051628 | Fang | Mar 2010 | A1 |
20100072268 | Johnson | Mar 2010 | A1 |
20110192859 | Belford | Aug 2011 | A1 |
20120228318 | Martin | Sep 2012 | A1 |
20130200089 | Vidal | Aug 2013 | A1 |
Number | Date | Country |
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WO2007099114 | Sep 2007 | WO |
Number | Date | Country | |
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20190135523 A1 | May 2019 | US |