KR101059251B1 - Cold pack - Google Patents

Abstract

The cold pack 10, 20, 30 of the present invention comprises an enclosure 11, 21, 31 with powdered solutes 12, 22, 32 and liquids 14, 24, 34 sealed in an enclosure. do. The powdered solute and liquid are sequestered by membranes 16, 26, 36 in the enclosure. The liquid and the powdered solute are mixed with each other to rupture the membrane to form an endothermic solution in the enclosure. Virtually all the powdered solute dissolves quickly in the liquid so that the cold pack quickly reaches the cooling temperature. In yet another embodiment, the cold pack includes absorbent cores 27, 37 in an enclosure. The absorbent core retains the endothermic solution to allow the endothermic solution to spread throughout the enclosure. By spreading the endothermic solutions 28 and 38 throughout the enclosure, the cooling temperature is evened out throughout the cold pack.

Description

Cold Pack {COLD PACK}

The present invention relates to a cold pack, and more particularly, to a cold pack placed in or near a human body to take heat from the body.

Various cooling methods are used to treat symptoms such as skin swelling, inflammation and muscle pain. One known cooling method involves placing ice inside the cloth and / or bag and placing the ice bag / cloth near the wound site of the body.

One problem with using ice is the rate at which heat is transferred from the body if heat is transferred too quickly from the skin, since it can cause damage to the skin. As the ice melts, its cooling capacity gradually decreases. Thus, ice can generally not be used for cooling purposes when the patient is away from the refrigerator, which keeps the ice frozen and stored.

Another method of cooling is to utilize cold packs that generate cooling through endothermic chemical reactions occurring inside. Cold packs generally contain a solute and a liquid, both of which are stored inside a common enclosure. The liquid and the solute are initially separated from each other inside the enclosure and then mixed with each other inside the enclosure to become an endothermic solution to lower the cold pack temperature.

One problem with such endothermic cold packs is that the solutes are in pellet form, so that when liquid and endothermic pellets mix with each other inside the enclosure, they sometimes do not adequately dissolve into solution. If the pellets dissolve too slowly (or not at all), the endothermic reactions in solution occur slowly and less efficiently than the endothermic reactions that can occur if all the endothermic pellets dissolve quickly in the liquid.

Another problem with endothermic cold packs is that the formation of the solution does not take place at the bottom of the enclosure, i. As the solution is made locally inside the enclosure, a temperature difference occurs inside the cold pack. The temperature difference that occurs inside the cold pack cools different parts of the wound at different rates.

Therefore, there is a need for a cold pack that uniformly cools body parts. Cold packs should also be easy to transport, and should be able to maintain a safe skin temperature for longer periods of time when the cold pack is placed on or near the body.

The present invention relates to a cold pack capable of generating an endothermic reaction therein. The endothermic reaction is generated by mixing the solute with a liquid to form an endothermic solution. The endothermic solution is produced faster inside the cold pack so that the cold pack can reach the cooling temperature faster. In addition, the quickly formed endothermic solution can be efficiently distributed throughout the cold pack, thereby making it possible to equalize the cooling temperature throughout the cold pack.

In one embodiment, the present invention is directed to a cold pack comprising an enclosure having a liquid sealed inside the enclosure and a powdered solute. Solutes and liquids are separated by membranes inside the enclosure. Rupture of the membrane causes the liquid to mix with the powdered solute, thus creating an endothermic solution inside the enclosure. Substantially all of the powdered solute quickly dissolves in the liquid so that the cold pack quickly reaches the cooling temperature.

In another embodiment, the present invention is directed to an enclosure and a cold pack comprising a solute and a liquid sealed within the enclosure. Liquids and solutes are separated by membranes inside the enclosure. Rupture of the membrane causes the liquid to mix with the solute, thus creating an endothermic solution inside the enclosure. The cold pack also includes an absorbent core inside the enclosure. The absorbent core retains the endothermic solution to spread the endothermic solution throughout the enclosure. Spreading the endothermic solution throughout the enclosure makes the cooling temperature more uniform throughout the cold pack.

In another embodiment, the present invention is directed to a cold pack comprising an enclosure. The powdered solute and liquid are sequestered by a membrane inside the enclosure. Rupture of the membrane quickly dissolves the powdered solute in the liquid, creating an endothermic solution inside the enclosure. The absorbent core is retained inside the enclosure to spread the endothermic solution throughout the enclosure. Virtually all the powdered solute dissolves quickly in the liquid to produce a fast-reacting endothermic solution that is uniformly spread throughout the cold pack by the absorbent core.

In yet another embodiment, the invention is directed to a method of cooling a body part. The method includes isolating the powdered solute from the liquid. The powdered solute and liquid are both inside the cold pack. The method further includes mixing the powdered solute and liquid with each other to form an endothermic solution inside the cold pack and placing the cold pack on a part of the body. As an example, mixing the powdered solute and liquid to form an endothermic solution involves rupturing a membrane that separates the powdered solute and the liquid inside the cold pack.

In another alternative embodiment, the method comprises isolating the solute and the liquid inside the cold pack, mixing the liquid and the solute to produce an endothermic solution inside the cold pack, distributing the endothermic solution throughout the cold pack, And placing a cold pack on a part of the body.

Dispensing the endothermic solution throughout the cold pack may include retaining the endothermic solution inside the absorbent core. Also, retaining the endothermic solution inside the absorbent core may include retaining the endothermic solution inside the absorbent layer.

In another alternative embodiment, the method includes isolating the powdered solute and liquid in the cold pack, and then mixing the powdered solute with the liquid to produce an endothermic solution inside the cold pack. The method further includes dispensing the endothermic solution throughout the cold pack and placing the cold pack on a portion of the body.

The objects and features of the present invention will be described below. Additional features of the invention will be realized and obtained by the objects and methods described in the description and claims, as well as the accompanying drawings.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and intended for further description of the invention. The accompanying drawings, which are incorporated in and constitute a part of this specification, are included for the convenience of description and understanding of the present invention.

The present invention will be more fully understood and other features will become apparent with reference to the following detailed description and accompanying drawings. The drawings are exemplary only and are not intended to limit the scope of the invention as set forth in the claims. Similar parts shown in the drawings are represented by the same drawings.

1 is a schematic cross-sectional view of a cold pack.

FIG. 2 is a schematic cross-sectional view of the cold pack shown in FIG. 1, showing that the endothermic solution is generated by rupture of the membrane inside the cold pack.

3 is a schematic cross-sectional view of another cold pack.

FIG. 4 is a schematic cross-sectional view of the cold pack shown in FIG. 3, in which a film is ruptured inside the cold pack to generate an endothermic solution. FIG.

5 is a schematic cross-sectional view of another cold pack.

FIG. 6 is a schematic cross-sectional view of the cold pack shown in FIG. 5 showing that the membrane ruptures inside the cold pack to produce an endothermic solution.

Hereinafter, a description will be given with reference to the accompanying drawings, which show specific embodiments in which the present invention is implemented. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It is to be understood that the following description is not to be taken in a limiting sense, that other embodiments may be utilized and that other structural modifications may be made.

1 and 2 show a cold pack 10. The cold pack 10 includes an enclosure 11 having a powdered solute 12 and a liquid 14 sealed therein. The powdered solute 12 and the liquid 14 inside the enclosure 11 are isolated from each other by a membrane 16 (see FIG. 1). When the membrane 16 is ruptured in such a way as to pressurize the enclosure 11, the liquid 14 (eg, water) and the powdered solute 12 are mixed with each other, and thus endothermic solution inside the enclosure 11. 18 is made (see Fig. 2). Substantially all of the powdered solute 12 quickly dissolves into the liquid 14 so that the cold pack 10 quickly reaches the cooling temperature.

The cold pack 10 may also include a thermal insulation layer 19 that insulates a portion of the enclosure 11 from the outside. It should be noted that the insulating layer 19 may be of any size or shape, and may be present inside or on the enclosure 11. The insulating layer 19 must be located on the side of the enclosure 11 opposite to the side of the enclosure 11 located on or near the body. If so, the thermal insulation layer 19 serves to reduce the warming of the cold pack 10 by ambient air without disturbing the transfer of heat from the body to the cold pack 10.

The film 16 may be made of polyethylene. In addition, any conventional solute may be used to cause an endothermic reaction inside the cold pack 10. An example of such a solute is ammonium nitrate. The pieces forming the powdered solute 12 should have a size between about 0.001 and about 0.025 inches, although smaller pieces may be used, or very few of the pieces may be larger than 0.025 inches.

3 and 4 show a cold pack 20. The cold pack 20 includes an enclosure 21 and a liquid 24 and a solute 22 sealed within the enclosure 21. The solute 22 and the liquid 24 (eg, water) are isolated from each other by a membrane 26 inside the enclosure 21.

Cold pack 20 includes an absorbent core, such as absorbent layer 27, inside enclosure 21 (see FIG. 3). The absorbent layer 27 retains an endothermic solution 28 formed inside the enclosure 21 by rupturing the membrane 26 (see FIG. 4). When the solute 22 and the liquid 24 are mixed with each other to make the endothermic solution 28 once, the absorbent layer 27 causes the endothermic solution 28 to be spread over the entire enclosure 21, so that the cold pack 20 The cold pack 20 cools the body wound evenly when on or near the body.

Membrane 26 may also isolate absorbent layer 27 from solute 22 and / or liquid 24 until membrane 26 ruptures and solute 22 and liquid 24 mix with each other. In some example embodiments, the solute 22 may be interspersed in the absorbent layer 27 before the membrane 26 is ruptured. The absorbent core may be made in other forms than the absorbent layer 27, or may be made of pulp fibers among other materials.

It should be appreciated that the solute 22 may be in pellet or powder form in the example of the cold pack 20 shown in FIGS. 3 and 4. The cold pack 20 may also include a thermal insulation layer 29 similar to the thermal insulation layer 19 described above with respect to FIGS. 1 and 2.

5 and 6 show a cold pack 30. Cold pack 30 includes an enclosure 31. The powdered solute 32 and the liquid 34 are isolated by the membrane 36 inside the enclosure 31 (see FIG. 5). By rupturing the membrane 36, substantially all of the powdered solute 32 in the liquid 34 is quickly dissolved, thereby creating an endothermic solution 38 inside the enclosure (see FIG. 6). By rapidly dissolving substantially all of the powdered solute 32 in the liquid 34, a rapid endothermic reaction can occur within the endothermic solution 38 that can quickly drop the temperature of the cold pack 30 to the cooling temperature.

An absorbent core, such as absorbent layer 37, is located inside of enclosure 31. The absorbent layer 37 spreads the rapidly reacting endothermic solution 38 throughout the cold pack 30 so that the cold pack 30 cools the body wound evenly and efficiently.

Membrane 36 may isolate absorbent layer 37 from solute 32 and / or liquid 34 until membrane 36 ruptures to mix solute 32 and liquid 34. In some example forms, the solute 32 may be interspersed in the absorbent layer 37 before the membrane 36 ruptures. The cold pack 30 may also include a thermal insulation layer 39 similar to the thermal insulation layer 19 described above with respect to FIGS. 1 and 2.

In some exemplary embodiments, the solute may be integrated with the absorbent layer as opposed to having the solute and the absorbent layer separated from each other. Although not specifically illustrated, exemplary embodiments of this type may include an enclosure and an absorbent layer filled with a solute within the enclosure and a membrane that initially separates the liquid from each other. Combining solutes and absorbent layers can simplify the manufacture of cold packs.

A method of cooling the body part will now be described with reference to FIGS. 1 and 2. In one form, the method comprises isolating the powdered solute 12 from the liquid 14, wherein the powdered solute 12 and the liquid 14 are located inside the cold pack 10 ( 1). The method mixes the powdered solute 12 and liquid 14 together to form an endothermic solution 18 inside the cold pack 10 (FIG. 2) and has the cold pack 10 on the body part. Includes more things to put on. In some exemplary forms of the method, mixing the pulverized solute 12 and the liquid 14 with each other to produce an endothermic solution 18 may cause the pulverized solute 12 inside the cold pack 10 to be liquid ( 14) to rupture the membrane 16 to isolate it.

Another form of the method will be described with reference to FIGS. 3 and 4. The method comprises isolating the solute 22 and the liquid 24 that are both present in the cold pack 20 (FIG. 3), and forming the endothermic solution 28 within the cold pack 22. And mixing the liquid 24 (FIG. 4), spreading the endothermic solution 28 throughout the cold pack 20, and placing the cold pack 20 on a part of the body. .

In some exemplary forms of the method, spreading the endothermic solution 28 throughout the cold pack 20 includes retaining the endothermic solution 28 inside an absorbent core, such as the absorbent layer 27. In some alternative forms, the method includes mixing the solute 22 and the liquid 24 within the absorbent layer 27. It should be appreciated that the solute 22 may be present in pellet or powdered form.

Another form of the method will be described with reference to FIGS. 5 and 6. The method includes isolating the powdered solute 32 and the liquid 34 in the cold pack 30 (FIG. 5). The method comprises mixing the powdered solute 32 with the liquid 34 to form an endothermic solution 38 inside the cold pack 30 (FIG. 6), and then cold endothermic solution 38. And spreading throughout the pack 30.

In various embodiments, the method may also include mixing the liquid 34 with the solute 32 within the absorbent layer 37. The method may also include placing the cold pack 30 on a body part.

The size and shape of the cold pack described herein will, among other factors, depend on the application for which the cold pack will be used. In addition, the membrane inside the enclosure may be of any size, number, arrangement, or configuration, provided that the membrane separates the solute from the liquid and (ii) the membrane ruptures so that the solute is mixed with the liquid to form an endothermic solution.

The steps of the method described above may be performed in a different order than the order described herein. It should be noted that attaching the cold pack to the body includes both direct and indirect attachment of the cold pack to the body. 1 to 6 are only representative and are not drawn due to strict accumulation. Some ratios may be exaggerated in the drawings, and some ratios may be reduced.

In another alternative form, the discharge layer (not shown) may be detachably mounted to the cold pack using an adhesive. The exit layer can be removed from the cold pack, leaving only the adhesive on the cold pack. The remaining adhesive provides a means for securing the cold pack directly or indirectly to the body, flexible wrap and / or other device.

The cold packs and methods described herein can be used to (i) quickly dissolve the powdered solute in the liquid to form an endothermic solution that reacts rapidly, and / or (ii) the endothermic solution throughout the cold pack. By spreading the cooling of the wound evenly.

While the invention has been described in detail with respect to specific embodiments thereof, it will be understood by those skilled in the art that the foregoing description pertains to modifications, variations, and Equivalent invention can be easily thought of.

Claims (14)

An enclosure, a powdered solute within the enclosure, a liquid within the enclosure, a membrane to segregate the powdered solute and the liquid, and a fiber layer within the enclosure, When the membrane is ruptured, the liquid and the powdered solute are mixed to produce an endothermic solution inside the enclosure, And the fibrous layer retains the endothermic solution inside the enclosure to spread the endothermic solution throughout the interior of the enclosure. The cold pack of claim 1 wherein each piece of powdered solute has a size between 0.001 inches (0.0254 mm) and 0.025 inches (0.635 mm). An enclosure, a solute in the enclosure, a liquid in the enclosure, a membrane to isolate the solute from the liquid, and an absorbent core in the enclosure, By rupturing the membrane, the liquid and solute are mixed with each other to produce an endothermic solution in the enclosure, And the absorbent core retains the endothermic solution to spread the endothermic solution throughout the enclosure. 4. The cold pack of claim 3 wherein said solute is a powdered solute. The cold pack of claim 3 wherein the absorbent core is an absorbent layer. The cold pack of claim 3 wherein the membrane isolates the absorbent core from the liquid. The cold pack of claim 6 wherein the absorbent core retains an endothermic solution when the membrane is ruptured. delete delete delete delete delete delete delete

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