RU44799U1 - SELF-HEATED OR COOLED CONTAINER - Google Patents

Abstract

A container with self-heating or self-cooling is proposed, containing a housing in which there are three cavities, one of which is for a substance that must be heated or cooled, and the other two are filled with reagents, when mixed, a chemical reaction with a thermal effect occurs, and are separated by a partition, a lid covering the cavity for said substance and means for destroying said partition, wherein the container body is made of a material selected from the group consisting of polypropylene, polyethylene and polyester.

Description

The utility model relates to a container with self-heating or self-cooling, in which reagents are located, when mixed, a chemical reaction with a thermal effect occurs.

Self-heating or self-cooling containers are known. Their advantage lies in the possibility of heating or cooling the products packaged in them, for example, food, namely soups, pasta with various sauces, coffee, chocolate, tea, beer, grappa, juices and other soft drinks, or, for example, non-food drinks, in particular paints, adhesives, lubricants and other household substances, to the desired temperature without the need for additional means of heating or cooling, and at any time at the request of the consumer. Such containers are very convenient, for example, outside the city, in the country, on train rides, in the car, on the plane, etc., where it is difficult to heat or cool the substances packaged in them. The heating or cooling of food or other products contained in such containers is ensured by a chemical reaction with a thermal effect that occurs when two reagents are mixed, which are placed in separate cavities in this container and which by themselves do not emit and do not absorb heat. Between the cavities in which these reagents are placed, there is a partition. When the consumer has a desire to preheat or cool the contents of the container before using or using it, he activates the destructive element built into the container, which breaks this partition, as a result of which the reagents are mixed, and a corresponding chemical reaction occurs in which heat is released or absorbed. Depending on what condition the product packaged in the container should be brought into, heated or chilled, reagents are placed in the container, when mixed, respectively, an exothermic (with evolution of heat) or endothermic (with absorption of heat) reaction occurs. As a rule, one reagent is water, and the second reagent for the exothermic reaction is calcium chloride, and for the endothermic reaction, sodium thiosulfate.

A well-known container for food products with self-heating or self-cooling is described in US patent No. 3970068 (07.20.1976; MKI ² : F 24 J 1/00, 65 V 25/22). This container contains a housing in which three cavities are made, one of which is intended for food products, and the other two are separated by a partition and filled with reagents, when mixed, a chemical reaction with

thermal effect. The container also contains a lid covering the cavity for food products, and means of destruction of the specified partition. In this container, the casing is made of metal or cardboard covered with aluminum foil, and the partition is made of synthetic resin. The body made of metal is durable, however, due to the high thermal conductivity of the metal body, when the product inside it is heated to a high temperature, the consumer may get burned, and upon cooling, will experience uncomfortable sensations associated with the contact of his fingers or lips with the cold surface of the container. The case, made of cardboard coated with aluminum foil, protects the consumer from burns or from the above unpleasant sensations, but is fragile.

The absence of these drawbacks associated with the risk of burns or with an uncomfortable sensation caused by the contact of the consumer’s fingers or lips with a cold surface distinguishes a container with self-heating or self-cooling, described in US patent No. 6705309 (03.16.2004, MKI ⁷ : F 24 J 1 / 00) and being the closest analogue of the proposed utility model. This container contains a housing in which three cavities are made, one of which is for a substance that must be heated or cooled, and the other two are filled with reagents, when mixed, a chemical reaction with a thermal effect occurs, and are separated by a partition, a lid that covers the cavity for the specified substance, and means of destruction of the specified septum. In this container, the outer side wall is made of three layers, while the inner layer is made of metal or plastic, the intermediate layer is made of corrugated cardboard, and the outer layer is made of polystyrene. In addition, the bottom of the container, which is the wall of the cavity for one of the reagents, is also made of polystyrene. Polystyrene has good thermal insulation properties, so that the consumer is protected from burns or from the above-mentioned uncomfortable sensations that are possible when the container is cooled. However, the implementation of the outer wall of the three-layer container significantly increases the cost of its manufacture, and the polystyrene used for the outer layer of the outer side wall and for the bottom is fragile and prone to cracking when internal stresses occur in it. Such cracks in the outer layer of the outer side wall of the container made of polystyrene or in its bottom can form, for example, when it falls or is squeezed, which can lead to reagents entering the environment. In particular, if such a reagent is calcium chloride, then its contact with human skin can lead to injuries. Another disadvantage of polystyrene is its harmful effect on the human body as in processing,

so when using. So, when polystyrene is heated above 60-80 ° C, styrene, plasticizers, fillers are released into the environment, which, when ingested in food and drinking water, adversely affect human health.

The task to which the proposed utility model is directed is to create a container with self-heating or self-cooling, when using which there is no risk of burns or other uncomfortable sensations for the consumer and which at the same time is quite durable and safe from the point of view of ecology and toxicity.

The solution to this problem is provided by the fact that in a container with self-heating or self-cooling, containing a housing in which there are three cavities, one of which is for a substance that must be heated or cooled, and the other two are filled with reagents, when mixed, a chemical reaction with thermal effect, and separated by a partition, a cover covering the cavity for the specified substance, and means for destroying the specified partition, the housing is made of a material selected from the group consisting of olipropilen, polyethylene and polyester.

The implementation of the housing of the proposed container from a material selected from the group consisting of polypropylene, polyethylene and polyester, with comparable thermal insulation properties of the latter with polystyrene, allows to obtain a significantly more durable container. This is ensured by the high resistance of polypropylene, polyethylene and polyester to the formation of cracks from internal stress and their high impact strength, the minimum value of which for these materials is 70 kJ / m ² , while the maximum impact strength of polystyrene is 50 kJ / m ² . In addition, polypropylene, polyethylene and polyester are practically the safest packaging materials for this purpose in terms of ecology and toxicity, and substances that can migrate from them into the environment are harmless. Polypropylene, polyethylene and polyester have good organoleptic characteristics, do not emit harmful substances into products and have good resistance to oils and fats. Thus, the proposed container is durable and safe from the point of view of ecology and toxicity, and when it is used there is no risk of burns or other uncomfortable feelings for the consumer.

In the proposed container, the partition between the cavities filled with reagents can be made of aluminum foil or of metallized polypropylene, polyethylene or polyester film.

The cavity for the substance to be heated or cooled may

be separated from one of the cavities filled with reagents, a partition, which is made of a material selected from the group consisting of polypropylene, polyethylene and polyester, and which is coated with aluminum foil from the side of the cavity filled with reagent.

The lid covering the cavity for the substance may be tear-off and made of aluminum foil or of metallized polypropylene, polyethylene or polyester film.

The proposed container may contain an additional removable lid, closing the container on the side of the lid, closing the cavity for the specified substance, and made of a material selected from the group consisting of polypropylene, polyethylene and polyester.

The body of the proposed container may consist of parts along the common axis in the form of inverted truncated cones, the adjacent bases of which have different diameters, while the cavity for the specified substance can be in the part with the base of a larger diameter.

The ratio of the height of the case to the height of its part with the base of a larger diameter can be from 2: 1 to 5: 4.

In a container intended for a substance that must be warmed up before use, this chemical reaction is exothermic.

In a container intended for a substance that must be cooled before use, the indicated chemical reaction is endothermic.

In a container in which said chemical reaction is exothermic, one reactant may be calcium chloride and the other water.

In a container in which the chemical reaction is endothermic, one reactant may be sodium thiosulfate and the other water.

An example implementation of the proposed container is described in detail below.

The essence of the utility model is illustrated in the drawing, schematically depicting a section of the proposed container.

An example implementation of the proposed utility model, described in detail below with reference to the accompanying drawing, relates to a self-heating food container, although a container intended for other products or designed to provide cooling of the products packaged in it has the same design.

The proposed container contains a housing 1, which consists of two parts 2 and 3 located along the common axis in the form of inverted truncated cones, the adjacent bases of which have different diameters, with part 2 with a larger diameter base located at the top, and part 3 with a base

smaller diameter is located below.

Three cavities are made in the housing 1, namely, cavity 4 filled with a food product, cavity 5 filled with a reagent, for example calcium chloride, when mixed with the second reagent, an exothermic reaction occurs, and cavity 6 filled with the specified second reagent, for example water.

In the described example, the container body 1 is made of polypropylene, however, it can also be made of polyethylene or polyester, the latter including materials such as polyethylene terephthalate, polycarbonate, polyethylene naphthalate, etc.

Although the housing shown in the drawing is made in the form of two parts located along the common axis in the form of inverted truncated cones, it can have a different shape. So, it can be made in the form of two cylindrical parts of different diameters located on the same axis, or in the form of two parts mounted on top of each other in the form of rectangular parallelepipeds, adjacent bases of which have different sizes, or in the form of two parts mounted on top of each other in the form cubes whose faces have different sizes, or in the form of two parts mounted on top of each other in the form of polygonal prisms, for example, triangular, quadrangular, pentagonal, hexagonal, etc., the adjacent bases of which there are different sizes, or in the form of two parts mounted on top of each other in the form of inverted truncated polygonal pyramids, for example, triangular, quadrangular, pentagonal, hexagonal, etc., adjacent bases of which have different sizes, while parts whose indicated base has smaller sizes can be located below, and the ratio of the height of the container body to the height of its upper part with a larger base can be from 2: 1 to 5: 4. The body of the proposed container may also have a handle, which can be made integral with it, and on its outer wall grooves for fingers, annular or longitudinal grooves or protrusions of semicircular, semi-oval, square, rectangular, polygonal, etc. can be made. profile.

According to the product to be packaged in a container, its cavities may have different volumes. So, in a container intended for grappa or epoxy, the volume of the cavity for it can be 20 ml, in the container intended for soup, the volume of the cavity intended for it can be, for example, 250 ml, and in the container intended for beer, the volume of the corresponding cavities may be, for example, 1000 ml. Thus, in the proposed container, the volume of the cavity for the substance to be heated or cooled can be from 20 ml to 1000 ml.

The cavity 6 is located in the lower part 3 of the housing 1 and is separated from the cavity 5 by a bursting partition 7 made of aluminum foil. Cavities 4 and 5 are located in part 2 with a base of a larger diameter, while cavity 4 is located in cavity 5 and is separated from it by a partition 8, also made of polypropylene and coated with aluminum foil from the side of cavity 5. The upper edge of the outer wall of the housing bounding the cavities 5 and 6 is bent outward and enveloped by the upper edge of the partition 8, attached by rolling. The cavity 4 is closed from above by a tear-off lid 9 made of aluminum foil and attached to the upper edge of the partition 8 by an adhesive joint. From above, from the side of the lid 9 covering the cavity 4, the container is closed by a removable lid 10 made of polypropylene. A cross-shaped incision (not shown in the drawing) can be made in the lid 10, in which a consumer can insert a straw before drinking, for example, a drink contained in a container and cooled in it. On the casing 1 of the container, from below, from below, there is a recess in which the bottom 11 of the casing 1 is located, made slightly convex.

In the cavity 6 there are means for destroying the partition 7 made in the form of three rectangular plates 12 extending from the bottom 11 of the container body 1 and made with it in one piece. The ends of the plates 12, opposite the bottom 11, are adjacent to the partition 7. Means of destruction of the partition between the cavities filled with reagents may also have a different design. They can be made in the form of a tubular element that extends from the bottom of the container body and the end of which, opposite the bottom, is adjacent to the specified partition. At the indicated end of this tubular element, an elongated cutout may be made for better passage of one reagent into a cavity filled with another reagent after the partition is destroyed. There can be several such cutouts, and they can extend from the end of the indicated element to the bottom of the container. The section of this element can be made round, triangular, square, rectangular, as well as in the form of any polygon, such as a pentagon, a hexagon, etc. This element can be made in one piece with the bottom.

The heating of the food product contained in the container is as follows.

When the consumer wants to warm up the product contained in the container, he turns the container upside down 11 and presses it. The bottom 11, when pressed, bends inward, and along with it the plates 12 made at the same time move, breaking through the partition 7, providing access to the water 6 located in the cavity 6 into the cavity 5, where calcium chloride is located. When mixing water with

calcium chloride a chemical reaction occurs with the release of a large amount of heat, under the influence of which the food product located in the cavity 4 is heated. The consumer must keep the container upside down for a certain time, shaking it to better mix the water with calcium chloride, so that the product contained in the container is heated to the required temperature. In the container shown in the drawing, the mass ratio of the food product, calcium chloride and water is chosen so that the temperature of the product rises by 45 ° from its initial temperature. The location of the cavity 4 in the cavity 5 provides heat from all sides of the cavity 4, except for the upper one, and the presence of an aluminum layer on the partition 8 between these cavities 4 and 5, which is on the side of the chemical reaction, allows to increase the heat transfer between these cavities.

After the lapse of time necessary for heating the food product located in the cavity 4, the consumer turns the container over with the bottom 11 down, removes the lid 10 and opens the lid 9, gaining access to the product.

The execution of the container body from polypropylene, polyethylene or polyester ensures its strength. This is achieved due to the high resistance of these materials to the formation of cracks from internal stress and high impact strength, which leads to their low tendency to brittle fracture. Due to this, the risk of damage to the container during its possible fall is minimized, and, therefore, the likelihood of reagents getting into the environment and their harmful effects on nearby people is minimized. In addition, polypropylene, polyethylene and polyester are almost the safest packaging materials for this purpose in terms of ecology and toxicity, and substances that can migrate from these materials are harmless. Polypropylene, polyethylene and polyester have good organoleptic characteristics, do not emit harmful substances into products and have good resistance to oils and fats, so containers made from these materials are suitable for long-term storage of ready-to-eat foods containing fats. In addition, they have good resistance to alcohol, so the proposed container is also suitable for long-term storage of alcoholic beverages, in particular beer, wine, grappa and so on. Thus, the proposed container is durable and safe from the point of view of ecology and toxicity, and the manufacture of its body from polypropylene, polyethylene or polyester having good thermal insulation properties, allows to protect the consumer from burns or from uncomfortable sensations that may occur when the container is cooled, if the latter is intended for a substance that must be refrigerated before use.

As indicated above, the proposed container may be intended for various food products, in particular for soups, pasta with various sauces, coffee, chocolate, tea, grappa, beer, juices and other soft drinks, as well as for non-food products, for example paints, lubricants, adhesives, in particular for epoxy, etc. For example, a container in which the specified product is epoxy resin can be very useful, for example, if necessary, perform adhesive bonding under conditions where it is not possible to heat the resin before mixing it with a hardener and aggregate.

Thus, the proposed utility model allows you to create a durable and easy-to-use container for food and non-food products with self-heating or self-cooling.

Claims (11)

1. A container with self-heating or self-cooling, comprising a housing in which there are three cavities, one of which is for a substance that must be heated or cooled, and the other two are filled with reagents, when mixed, a chemical reaction with a thermal effect occurs, and are separated by a partition , a lid covering the cavity for the specified substance, and means for destroying the specified partition, characterized in that the container body is made of a material selected from the group consisting of polypropylene, polyethe linen and polyester. 2. The container according to claim 1, characterized in that said partition is made of aluminum foil or of metallized polypropylene, polyethylene or polyester film. 3. The container according to claim 1, characterized in that the cavity for the specified substance is separated from one of the cavities filled with reagents, a partition, which is made of a material selected from the group consisting of polypropylene, polyethylene and polyester, and which is on the side of the cavity filled reagent coated with aluminum foil. 4. The container according to claim 1, characterized in that the lid covering the cavity for the specified substance is tear-off and made of aluminum foil or of metallized polypropylene, polyethylene or polyester film. 5. The container according to claim 1, characterized in that it contains an additional removable lid that covers the container from the side of the lid that closes the cavity for the specified substance, and is made of a material selected from the group consisting of polypropylene, polyethylene and polyester. 6. The container according to claim 1, characterized in that its body consists of parts located along the common axis in the form of inverted truncated cones, the adjacent bases of which have different diameters, while the cavity for the specified substance is in the part with the base of a larger diameter. 7. The container according to claim 6, characterized in that the ratio of the height of the housing to the height of its part with the base of a larger diameter is from 2: 1 to 5: 4. 8. A container according to any one of claims 1 to 7, characterized in that said chemical reaction is exothermic. 9. A container according to any one of claims 1 to 7, characterized in that said chemical reaction is endothermic. 10. The container of claim 8, wherein one reagent is calcium chloride, and the other is water. 11. The container according to claim 9, characterized in that one reagent is sodium thiosulfate, and the other is water.