RU2021199C1 - Container for storing mineral water - Google Patents

Abstract

FIELD: mechanical engineering; mineral water reservoirs. SUBSTANCE: mineral water saturated with carbon dioxide is admitted into housing 1 under pressure via siphon tube 9. Housing 1 has cover 5 provided with discharge and drain valves 6 and 12. Nozzle 10 is attached to lower end of siphon tube 9. Radial micropassages disposed around periphery of nozzle 10 provide communication between inner space of housing 1 and siphon tube 9. Total cross-sectional area of micropassages does not exceed that of siphon tube 9. Mineral water flowing out of micropassages of nozzle 10 gives off minute bubbles of carbon dioxide which form protective layer over surface of mineral water outflow. EFFECT: more sophisticated design. 2 dwg

Description

 The invention relates to containers for transportation, storage and dispensing of liquids and can be used for refueling and storage of mineral water.

 Closest to the claimed invention is a container for storing mineral water, comprising a housing, a cover with a drain valve and a fitting. When filling the tank, mineral water saturated with carbon dioxide is poured into the casing, and the remaining free volume is filled with carbon dioxide to a certain level.

 A disadvantage of the known tank is that when the tank is filled with mineral water, it is oxidized by atmospheric oxygen, since when mineral water saturated with carbon dioxide enters the tank body, gas is released from the water in the form of large bubbles immediately after leaving the tube, i.e. directly in the area adjacent to the tube. Therefore, most of the surface of mineral water is in contact with air, especially in the initial period of filling the tank.

 It is known that when mineral water comes in contact with atmospheric oxygen, its physicochemical composition changes and the therapeutic effect decreases.

 The basis of the invention is the creation of such a tank for storing mineral water, in which when refueling it would eliminate the oxidation of water with atmospheric oxygen.

 The problem is solved in that in the container for storing mineral water containing a housing with a siphon tube, a cover with a drain valve and a fitting, according to the invention, nozzles are installed at the lower end of the siphon tube, having radial microchannels located around the circumference connecting the cavity of the case with a siphon tube, in this case, the total cross-sectional area of the microchannel holes is not larger than the cross-sectional area of the holes of the siphon tube, and a drain valve is installed on the lid of the tank.

 The advantages of the proposed design of the tank are that due to the presence of the nozzle of the specified design ensures uniform emission of carbon dioxide simultaneously over the entire surface of the mineral water in the cavity of the housing.

 The specified technical result is achieved due to the fact that when passing mineral water saturated with carbon dioxide through the channels of the nozzle, it is crushed into separate jets, which are distributed at a fairly high speed evenly over the entire cross section of the container cavity. In this case, due to the drop in water pressure when it enters the body cavity, carbon dioxide spontaneously releases in the form of small bubbles also simultaneously over the entire cross section of the tank, forming a protective layer over the entire surface of the mineral water and isolating the mineral water from the air in the tank, especially it is important in the initial period of refueling.

 Air is displaced from the tank through the drain valve until the tank is completely filled with mineral water.

 In FIG. 1 shows a General view of the tank (cross section); figure 2 - node I in figure 1.

 The container contains a housing 1, with a glass 2 fixed in its upper part and heating 3 and temperature-regulating elements 4 located therein, a cover 5 with a drain valve 6, a fitting 7, a key 8 and a siphon tube 9, the upper end of which is located in the glass 2, and nozzles 10 with radial microchannels 11 located around the circumference and connecting the cavity of the housing 1 with a siphon tube 9 are strengthened at its lower end, while the total cross-sectional area of the microchannels is not more than the cross-section of the siphon tube opening, on the cover 5 located drain valve 12.

 To fill the tank, carbonated saturated mineral water is supplied to the housing 1 under pressure through a siphon tube 9. When it enters radial microchannels 11, the total cross-sectional dimension of which is less than or equal to the cross-sectional size of the siphon tube channel 9, mineral water with a sufficiently high the nozzle 10 exits the microchannels 11 and is evenly distributed over the entire cross section of the cavity of the housing 1. In this case, due to a drop in water pressure when it enters the cavity of the housing 1, it spontaneously stands out from the water I carbon dioxide in the form of small bubbles evenly over the entire cross section of the tank, forming a protective layer over the entire surface of the water and isolating the mineral water from the air, due to which its physicochemical composition and healing properties are preserved. Air is displaced from the housing 1 through the drain valve 12 until the container body is completely filled with mineral water, thereby achieving full utilization of the volume of the container body.

 Before the water is supplied from the tank, a heating element 3 is turned on, which produces heating of the liquid in the glass 2 to a certain temperature supported by the temperature-regulating element 4. After heating, press the key 8 and water under the pressure of the gas located in the mineral water (in the tank) via a siphon tube 9 through the drain valve 6 and the fitting 7 enters the consumer. The freed volume of the tank is filled with carbon dioxide released from mineral water.

Claims (1)

 MINERAL WATER STORAGE CONTAINER, comprising a housing, a siphon tube, a cover with a drain valve and a fitting, characterized in that a nozzle is installed at the lower end of the siphon tube, having radial microchannels located around the circumference connecting the cavity of the casing with the siphon tube, and the total transverse area the cross section of the openings of the microchannels does not exceed the cross-sectional area of the opening of the siphon tube, and a drain valve is installed on the lid.

Images