ITSS20120001A1 - SELF-REFRIGERATING ALUMINUM BOTTLE WITH SINGLE BLOCK BELL INNER CYLINDER. - Google Patents

Description

DESCRIPTION

having the title

- AUTO REFRIGERANT ALUMINUM BOTTLE WITH CYLINDER

INTERNAL BELL SINGLE BLOCK

The present invention provides an aluminum self-refrigerating bottle (1) equipped inside with a housing compartment (12a) having a volume (13a) equal to 50% of the internal volume of the bottle. This compartment (12a) will be used to house the components (22c-23c). The geometry of the internal compartment is cylindrical (12a) and with a rounded bell-shaped upper part. This form allows to promote the cooling rate of a drink (26a) considered hot. This geometry (12a) also allows the possibility of ensuring the maximum heat exchange surface with the beverage (26a). The compartment (12a) is designed to be housed inside the bottle (l), joined to it and inside in a single mold, also in aluminum alloy like the bottle container (1) and diametrically lower than it , having the basic function of externalizing, through the wall (24b) the cold generated by the compartment (1 2), also called "heat exchanger". The internal bottle compartment (12a), has walls of the same thickness (24c ) of the bottle walls (2a-2b). This cavity will contain within it a quantity of water (22c) and one of ammonium nitrate and other components - (23c) (EU regulated), separated and isolated from each other by a pvc separator ring (16a), equipped with an extremely thin plastic rupture membrane (17a) positioned in the surface of the separator ring. The membrane (17a) is hot glued on the surface of the pvc separator ring (16a) The separating ring (16a) is located and placed approximately six centimeters from the base of the bottle and inside compartment 1 (1 2a). The bottle bottom cap () is designed with the external part in very rigid pvc, instead the central part will be much softer and more flexible, this in order to be able to exert a manual pressure from the bottom up. This pressure has the function of pushing the priming piston (20a) and the whole mixing system which is positioned in the center of the cap and inside the exchanger compartment (12a) in the base of the bottle bottom (21a). The rupture plate (19a) equipped with small pvc rupture needles (18a), positioned a few millimeters from the membrane (17a), is joined to the piston (20a). This slight push of the bottom cap (21a) towards the top of the bottle causes the break of the internal membrane (17a), causing the fall of the water positioned inside the compartment (22a), in the compartment (23a), where the powder is positioned. of the formula based on ammonium nitrate (23c). In this way the two elements will mix together. Furthermore, the rupture plate is provided with eight circular holes (19d) which will allow the water to flow more easily towards the compartment (23a). The mixing of the two components (22a and 23a) generates a drop in the temperature inside the compartment (12a) down to "minus five degrees centigrade from the external starting temperature". From that precise moment the heat exchange between the drink and the internal cooling system will begin, bringing the temperature of the drink to a rapid cooling. The mixing of the two components - water (22c) and formula based on ammonium nitrate (23c), will be accentuated by a slight manual semi-rotating movement that will help accelerate the cooling of the drink (26a). This cooling system through reaction - water and a new formula based on ammonium nitrate and other products - is well known and exploited in the hospital trauma field (see dry ice) and in the agricultural fertilization sector. The aforementioned invention could be immediately industrializable.

Details of the internal bottle compartment (12a):

The cavity of the compartment (12a) comprises a wall (24a) in contact with the beverage (26a) to be cooled. The wall (24a) allows to separate and isolate the communication between the exchanger compartment (12a) and the drink (26a).

The diameter of the bottle bottom cap (21a) is calculated on the basis of the volume (3a) and the shape of the aluminum bottle (1) The bottom cap (21a) is joined in a single fusion with the elements 20a - 19a - 18a.

This invention complies with the European regulation of chemicals (ammonium nitrate) EC Regulation 552/2009 published on the Official Gazette. of the European Union of 26/06/2009)

Main characteristics of the self-refrigeration system

of an aluminum bottle for drinks

For a specific feature, the self-refrigerating aluminum bottle allows the starting temperature of the drink to be reduced by up to 70%. Due to a specific characteristic, the drink is never in contact with the coolant.

Due to a specific characteristic, the materials used to generate self-refrigeration are totally recyclable.

Due to a specific feature, the self-refrigeration system inserted in the aluminum bottle does not generate any pressure or implosion inside the cylindrical "heat exchanger" compartment.

For a specific characteristic, the self-refrigeration system is never subject to self-combustion and in no case can it be tampered with to generate exploded views.

Due to a specific characteristic, the ammonium nitrate-based formula for self-refrigeration has a PH lower than five.

For a specific feature, the self-refrigerating aluminum bottle is totally recyclable.

For a specific feature, the self-refrigerating aluminum bottle brings enormous energy savings.

For a specific feature, the self-refrigerating aluminum bottle is impact resistant.

For a specific characteristic, the self-refrigerating aluminum bottle can be industrialized.

For a specific characteristic, the self-refrigerating aluminum bottle will only affect the price of the normal beverage sold in bottles or cans by 20%.

For a specific feature, the self-refrigerating aluminum bottle system can be applied to different quantities of bottled beverage.

For a specific characteristic, the self-refrigerating aluminum bottle offers the bottling companies that will apply this system a greater industrial and commercial expansion.

For a specific feature, the self-refrigerating aluminum bottle is easy to transport and not bulky.

For a specific feature, the self-refrigerating aluminum bottle cools the drink contained within it up to 50% of the original volume of the bottle.

For a specific feature, the self-refrigerating aluminum bottle allows you to contain a sufficient quantity of drink inside to quench a person's thirst.

For a specific feature, the self-refrigerating aluminum bottle is an innovative system in the beverage marketing industry.

For a specific feature, the self-refrigerating aluminum bottle does not contain gases that are harmful to the environment.

Claims (1)

CLAIMS IN ITALIAN having the title - SELF-REFRIGERATING ALUMINUM BOTTLE WITH INTERNAL CYLINDER A SINGLE BLOCK BELL The present invention provides an aluminum self-refrigerating bottle (1) equipped inside with a housing compartment (12a) having a volume (13a) equal to 50% of the internal volume of the bottle. This compartment (12a) will be used to house the components (22c-23c). The geometry of the internal compartment is cylindrical (12a) and with a rounded bell-shaped upper part. This form allows to promote the cooling rate of a drink (26a) considered hot. This geometry (12a) also allows the possibility of ensuring the maximum heat exchange surface with the drink {26a). The compartment (12a) is designed to be housed inside the bottle (1), joined to it and inside in a single mold, also in aluminum alloy like the bottle container (l) and diametrically lower than the same, having as its basic function that of externalizing, through the wall {24b) the cold generated by the compartment (1 2), also called "heat exchanger". The internal bottle compartment (12a) has walls of the same thickness (24c) as the bottle walls (2a-2b). This cavity will contain within it a quantity of water (22c) and one of ammonium nitrate and other components (23c) (EU regulated), separated and isolated from each other by a PVC separator ring (16a), provided with an extremely thin plastic rupture membrane (17a) positioned in the surface of the separator ring. The membrane (17a) is hot glued to the surface of the pvc separator ring (16a). The separator ring (16a) is located and placed about six centimeters from the base of the bottle and inside compartment 1 (1 2a). The bottle bottom cap (21a) is designed with the external part in very rigid pvc, instead the central part will be much softer and more flexible, in order to be able to exert a manual pressure from the bottom up. This pressure has the function of pushing the priming piston (20a) and the whole mixing system which is positioned at the center of the cap and inside the exchanger compartment 12a) into the base of the bottle bottom (21a). The rupture plate (19a) equipped with small rupture needles in pvc {18a), positioned a few millimeters from the membrane (17a), is joined to the piston (20a). This slight push of the bottom cap (21a) towards the top of the bottle generates the breakage of the internal membrane (17a), causing the fall of the water positioned inside the compartment (22a), in the compartment (23a), where it is positioned the powder of the formula based on ammonium nitrate (23c). In this way the two elements will mix with each other. Furthermore, the rupture plate is provided with eight circular holes (19d) which will allow the water to flow more easily towards the compartment (23a). The mixing of the two components (22a and 23a) generates a drop in the temperature inside the compartment (12a) down to "minus five degrees centigrade from the external starting temperature". From that precise moment the heat exchange between the drink and the system will begin internal cooling, bringing the temperature of the drink to a quick cooling. The mixing of the two components - water {22c) and formula based on ammonium nitrate (23c), will be accentuated by a slight manual semi-rotating movement that will help the acceleration of the cooling of the beverage (26a). This cooling system through reaction - water and a new formula based on ammonium nitrate and other products - is well known and exploited in the hospital trauma field (see dry ice) and in the agricultural fertilization sector. The aforementioned invention could be immediately industrializable. Details of the internal bottle compartment (12a): The cavity of the compartment (12a) comprises a wall (24a) in contact with the beverage (26a) to be cooled. The wall (24a) allows to separate and isolate the communication between the exchanger compartment 12a) and the drink (26a). The diameter of the bottle bottom cap (21a) is calculated on the basis of the volume (3a) and the shape of the aluminum bottle (1) The bottom cap (21a) is joined in a single fusion with the elements 20a - 19a - 18a. This invention complies with European regulations on chemicals. {Ammonium nitrate) EC Regulation 552/2009 published on the Official Gazette of the European Union of 26/06/2009)