Thermal-transfer container sleeve system and method

Abstract

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.

Claims

1. A thermal-transfer container sleeve method for affecting the temperature of a fluid inside a thermally-conductive container, comprising: (i) providing a thermal-transfer container sleeve, further comprising: (a) a plurality of high-thermal capacitance units adapted to transfer thermal energy with an outside heat source or sink, store such thermal energy, and transfer such thermal energy with the fluid inside a thermally-conductive container, and having an inner face adapted for thermal contact with the thermally-conductive container; and (b) an insulating sleeve of thermally-insulating sheet material, having an inner face toward the thermally-conductive container and an opposite outer face, adapted for attachment of said high-thermal-capacitance units on the inner face, and adapted for holding said high-thermal-capacitance units on the inner face; and adapted for holding said high-thermal-capacitance units against the surface of the thermally-conductive container; where the shape of said high-thermal-capacitance units and configuration of attachment to said insulating sleeve are such that the inner face of each high-thermal-capacitance unit has a curved surface between a plurality of side walls, and when placed upon the thermally-conductive container, each side wall abuts a side wall of an adjacent high-thermal-capacitance unit, and the curved surfaces of the plurality of high-thermal capacitance units form a continuous surface conforming to the shape of, and in continuous contact with, the thermally-conductive container, and when removed from the thermally-conductive container the inner faces of said high-thermal-capacitance units are located further apart; and where no energy source other than the stored thermal energy of said high-thermal-capacitance units is used by said thermal-transfer container sleeve when in use upon the thermally-conductive container; and (ii) using said thermal-transfer container sleeve by first pre-heating or pre-cooling by an outside heat source or sink, and then placing upon the thermally-conductive container of fluid such that the inner faces of said high-thermal-capacitance units are held in thermal contact with the thermally-conductive container by said insulating sleeve.

2. The thermal-transfer container sleeve method of claim 1, where said thermal-transfer container sleeve further comprises sleeve closures adapted to facilitate placement and removal in use.

3. The thermal-transfer container sleeve method of claim 1, where said thermal-transfer container sleeve further comprises an access opening adapted to allow access to an opening in the thermally-conductive container of fluid during use.

4. The thermal-transfer container sleeve method of claim 1, where said insulating sleeve is made of a flexible sheet rubber material.

5. The thermal-transfer container sleeve method of claim 1, where said insulating sleeve is made of a silicone sheet material.

6. The thermal-transfer container sleeve method of claim 1, where said high-thermal-capacitance units are made of metal.

7. The thermal-transfer container sleeve method of claim 1, where said high-thermal-capacitance units are made of ceramic material.

8. The thermal-transfer container sleeve method of claim 1, where said high-thermal-capacitance units are made of copper.

Description

BRIEF DESCRIPTION OF DRAWINGS

(1) Reference will now be made to the drawings, wherein like parts are designated by like numerals, and wherein:

(2) FIGS. 1A through 1D illustrate the thermal-transfer container sleeve of the invention in use on a beverage container, with FIG. 1A illustrating the thermal-transfer container sleeve of the invention laid flat, prior to use on a beverage container, FIG. 1B illustrating the thermal-transfer container sleeve of the invention partially rolled, FIG. 1C illustrating the thermal-transfer container sleeve of the invention partially rolled around a beverage container, and FIG. 1D illustrating the thermal-transfer container sleeve of the invention fully rolled around a beverage container;

(3) FIG. 2 is a perspective view of an embodiment of the thermal-transfer container sleeve of the invention having an access opening;

(4) FIG. 3 is a schematic view of the thermal-transfer container sleeve of the invention in use on a person's arm and wrist;

(5) FIG. 4 is a schematic view of the thermal-transfer container sleeve of the invention in use to warm a bag of blood for transfusion;

(6) FIGS. 5A and 5B illustrate a stretch embodiment of the thermal-transfer container sleeve of the invention in use on a bottle, with FIG. 5A illustrating the stretch embodiment of the thermal-transfer container sleeve of the invention prior to application on a bottle, and FIG. 5B illustrating the stretch embodiment of the thermal-transfer container sleeve applied to and stretched around the outside of a bottle;

(7) FIGS. 6A through 6C illustrate a stepped-sided container embodiment of the thermal-transfer container sleeve of the invention in use, with FIG. 6A illustrating a matching-container embodiment of the thermal-transfer container sleeve prior to application around a stepped-sided container, FIG. 6B illustrating a sample stepped-sided container, prior to having a matching-container embodiment of the thermal-transfer container sleeve applied to the container, and FIG. 6C illustrating the matching-container embodiment of the thermal-transfer container sleeve in application around a stepped-sided container; and

(8) FIG. 7 is a perspective view of an alternative embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

(9) Referring to FIGS. 1A through 1D, the thermal-transfer container sleeve system 10 of the invention is shown in use on a beverage container. The fluid containers appropriate for this thermal-transfer container sleeve 10 are made of thermally-conductive material, such as metal, plastic, paper, or glass, in contrast to an insulating material, which would tend to prevent the desired thermal transfer.

(10) 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.

(11) 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.

(12) 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 FIGS. 1C and 1D, the inner faces of the high-thermal-capacitance units 2 are brought together, and an essentially gap-free array of high-thermal-capacitance units 2 make contact with the outer surface of the fluid container.

(13) 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.

(14) 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.

(15) 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.

(16) Referring to FIG. 2, optionally, an access opening 5 is provided to accommodate a person's mouth when drinking from the container. The cutout 5 can be configured with straight sides or curved sides for the comfort of the user.

(17) Referring to FIG. 3, the thermal-transfer container sleeve system 10 can also be used to provide heat or cold for medical or therapeutic uses. For such uses, it may be preferable to choose a material for the high-thermal-capacitance units 2 that exhibit a longer, more gradual and gentle addition or subtraction of heat, in order to prevent damage to skin and tissue. A protective cloth can be placed between the high-capacitance units 2 and the user's skin. If the system 10 is used as a heating pad, it will provide an added advantage that other heating pads do not; by wetting the protective cloth, it will provide moist heat, as opposed to dry heat, which is more desirable in many cases.

(18) Referring to FIG. 4, the thermal-transfer container sleeve system 10 can be used to bring blood and other fluids up to a useable temperature in a quick but controlled way. Blood must be kept cold up until time of transfusion, but must be warmed just before use, often under time-sensitive conditions, and sometimes away from heating devices such as ovens. The thermal-transfer container sleeve system 10 makes contact with most of the surface area of the bag-like fluid container, and transfers heat, in this case, into the fluid in an even manner, avoiding localized overheating which would damage the blood.

(19) Referring to FIGS. 5A and 5B, a stretch embodiment 20 of the thermal-transfer container sleeve is provided, which is appropriate for fluid containers having irregular profiles, such as certain beverage bottles. In the stretch embodiment depicted in FIGS. 5A and 5B, the insulating sleeve system comprises an insulating stretch sleeve 21, of a material such as neoprene. Arrayed upon the inside surface of the insulating stretch sleeve 21 are several separate high-thermal-capacitance units 22 which are not long bars of high-thermal-capacitance material, but are instead smaller separate units which can move in relation to each other as the insulating stretch sleeve 21 expands or contracts to follow the profile of the fluid container.

(20) Referring to FIGS. 6A through 6C, a matching-container embodiment 30 of the thermal-transfer container sleeve additionally provides a stepped-sided container 33 that has an increased surface area created by alternating concavities and convexities of the container sides, as shown. This effect can be achieved with a variety of patterns, from smooth undulations to sharper edges. Depending upon the container material and the container's purpose, there may be advantages of mechanical strength or production technique for one pattern over another. In this matching-container embodiment, the configuration of the high-thermal-capacitance units 2 is designed to conform to the pattern of the stepped-sided container 33 such that a maximum amount of close physical and thermal contact is achieved.

(21) 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.

(22) Turning now to the alternative embodiment of the present invention shown in FIG. 7, the cooling system comprises a plurality of thermally-conductive units, or members 42. The thermally-conductive units 42, similarly to the units 2, are formed from a solid thermally-conductive material, such as, for instance, ceramics, polymers and others. Such materials have high-melting point and will not melt when exposed to room temperature, as opposed to ice cubes made from water.

(23) 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.

(24) 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.

(25) 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.