RU144698U1 - WATER DISPENSER WITH AN OVER-PRESSURE OVEN STERILIZATION SYSTEM OF OVER-PRESSURE AIR - Google Patents

Abstract

A water dispenser for dispensing drinking water from an inverted bottle, comprising a housing, a funnel mounted on the outer surface of the housing for installing the bottle upside down and an intake finger mounted on the bottom of the funnel equipped with separate air and water channels. The dispenser is additionally equipped with an ozone generator and an air pump connected by an air pipe to the air channel of the water finger, and is also equipped with a water pipe connected to the water channel of the water finger and equipped with a water valve. The technical result of the utility model is to provide the ability to maintain a clean air environment in a bottle of a water dispenser.

Description

The invention relates to bottle-type water dispensers in which drinking water is dispensed from an inverted bottle.

In the simplest case, such a dispenser is a storage tank for water with a tap, onto which a bottle is turned upside down. Water flowing out of the bottle fills the storage tank until the water level in the storage tank reaches the neck of the bottle, after which the flow of water from the bottle stops. When the consumer draws water, the water level in the storage tank drops, and water again flows from the bottle into the storage tank.

The disadvantage of this device is the ingress of untreated atmospheric air into the bottle. Bacteria and plant spores contained in the air, once in a bottle, begin to develop there, worsening the quality of the water. In addition, with this design of the dispenser, contaminants from the outer surface of the neck of the bottle may enter the storage tank.

Therefore, in modern bottle-type water dispensers, rigid hard bottles with a volume of 5 to 20 liters are used, equipped with special closures that are uncorked when the bottle is installed on the dispenser and automatically corked when the bottle is removed from the dispenser, thereby protecting it from spilling water and from getting into it into a bottle of microorganisms from the environment. When installing the bottle on the dispenser, the water intake finger enters the neck of the bottle, moving the cork inside the bottle, and when you remove the bottle, the water intake finger, leaving the bottle neck, pulls the cork along with it, ensuring a tightly clogged bottle.

Closest to the proposed technical solution is a water dispenser, US patent No. 5,526,961 comprising a housing, a funnel mounted on the outer surface of the housing for installing the bottle upside down, an intake finger mounted on the bottom of the funnel, equipped with separate air and water channels, a storage tank for water, from which distributes water to consumers, and a filter for cleaning atmospheric air entering the airspace of the storage tank.

The disadvantage of this device is also the ingress of atmospheric air into the bottle and the inability to maintain a safe air environment in the bottle for a long period, since the air filter does not allow for complete filtration from microbiological contamination.

The objective of the invention is to provide the ability to maintain a sterile air environment in a bottle of water dispenser.

The technical result is achieved in that in a water dispenser for dispensing drinking water from an inverted bottle, comprising a housing, a funnel mounted on the outer surface of the housing for installing an inverted neck down the bottle, a water finger installed on the bottom of the funnel equipped with separate air and water channels, an additional generator is introduced ozone and an air pump connected by an air pipe to the air channel of the water intake finger, and also a water pipe connected to the water channel of the water intake molecular pin and provided with water valve.

It is desirable that the air pump provides an overpressure in the bottle from 0.01 to 0.3 atm. It is preferable to operate the device with a pump that provides overpressure in the bottle from 0.05 to 0.2 atm. Most preferably, if the device comprises a pump providing an overpressure in the bottle of about 0.1 atm.

The dispenser may further comprise an instantaneous water cooling device included in the water pipeline to cool the water dispensed to the consumer. The flow cooling device included in the water pipeline does not violate the continuity of the pipeline, and does not affect the maintenance of a sterile atmosphere in the bottle.

It is possible to additionally equip the dispenser with an electronic control device that controls the operation of the pump and the ozone generator in accordance with the recorded program. This device can also control the operation of the water valve and the instantaneous water cooling device, if any.

Preferably, if the water intake finger is equipped with a bottle opening device to ensure automatic opening of the bottle when the bottle is installed on the dispenser, and a bottle clogging device when the bottle is removed from the dispenser. The presence of such a device protects against atmospheric air and the microorganisms contained in it when the bottle is opened, and protects it from spilling water from the bottle when installing and removing the bottle.

A protective air valve can be installed in the air pipe to prevent water from entering the pipe. It is desirable that the air pipe be made of ozone-resistant material.

The dispenser can be additionally equipped with a bottle presence sensor and an air pressure sensor in the air pipe. These sensors can be connected to an electronic control device that controls the operation of other dispenser devices.

BRIEF DESCRIPTION OF THE DRAWINGS

In FIG. 1 schematically shows the proposed dispenser;

in FIG. 2 - sectional water intake finger;

in FIG. 3 - appearance of the dispenser;

in FIG. 4 - design of a dispenser with a device for flow cooling water.

The water dispenser shown in FIG. 1, includes a housing 1, a funnel 2 for installing the bottle 3 upside down, an intake finger 4, an air pipe 5 connecting the intake finger 4 to the ozone generator 6 and the air pump 7, a water pipe 8 connecting the intake finger 4 to the water valve 9. An air valve 10 is inserted into the air pipe 5. The intake finger 4 is provided with two separate channels, an air channel 11 and a water channel 12. At the top of the water intake finger 4 there is a device 13 for opening the bottle.

The design of the water finger is shown in section in FIG. 2. Two channels are made inside the intake finger 4 — the air channel 11 and the water channel 12. The inlet of the air channel 11 is connected to the air pipe 5, and the outlet is at the top of the water finger 4. In turn, the inlet of the water channel 12 is at the top water finger 4, and the output is connected to the water pipe 8.

The appearance of the dispenser is shown in FIG. 3. On the upper outer surface of the dispenser 1 housing there is a funnel 2 for installing the bottle 3. On one of the side surfaces there is a nozzle 14, from which water flows into the container that the consumer substitutes. On the same side surface is the dispenser control panel. In the simplest version, the panel can contain only one button - the button for issuing water 17.

If necessary, the dispenser can be additionally equipped with a device for flow cooling water. A schematic representation of such a dispenser is shown in FIG. 4. The flow cooling device 18 is included in the water channel 8 in front of the water valve 9. The refrigerator, for example, of the thermoelectric type, contained in the device cools the walls of the water channel 8 and through them the water flowing through the channel 8. The flow-type water cooling device compares favorably with the devices cooling with storage tanks. The use of flow cooling does not violate the tightness of the interior of the dispenser in contact with water and does not create a potential source of contamination.

The proposed water dispenser operates as follows. The first inclusion of the dispenser is preferably done without a bottle installed. When the dispenser is turned on without a bottle, the air pump 7 and the ozone generator 6 are turned on. Ozone through the air pipe 5 enters the air channel 11 of the intake finger 4, and from there through the hole in the upper part of the water intake finger 4, the ozone exits and fills the inner space of the funnel 2, thereby disinfection of the air channel 11 of the finger 4, and to some extent the outer surface of the finger 4 and the inner surface of the funnel 2, is carried out. This also opens the water valve 9, and part of the ozone from the air channel Ala 11, the water intake finger 4 flows into the water channel 12, and from there into the water pipe 8, disinfecting their internal surfaces. When you turn on the dispenser for the first time or, if necessary, in enhanced processing of the water channel, for example, after a long break in work, it is possible to use a special capsule cap. The capsule-cap is an inverted glass or cup shaped to fit into the funnel 2 over the intake finger 4, so that the walls of the funnel 2 and the capsule form a closed space around the intake finger. At the same time, ozone leaving the air channel will fill this closed space and the open water channel, sterilizing the outer surface of the water finger 4 and the inner surface of the water channel 8. After that, the water valve 9 closes, a new full bottle of 3 with drinking water turns its neck down and sets on the intake finger 4, while the neck of the bottle 3 rests on the bottom of the funnel 2, and the walls of the bottle 3 rest on the walls of the funnel 2. The air pump 7 and the ozone generator 6 continue to work as long as the pressure e air in the bottle 3, and an air pipe 5 reaches the predetermined threshold of 0.01-0.3 atm. The pressure can be measured by an air pressure sensor installed in the air pipe 5, in the pump itself or in some other way, for example, by changing the current consumption of the air pump 7. After reaching a predetermined threshold, the air pump 7 is turned off, and after a while after it is turned off and ozone generator 6. To avoid getting into the bottle 3 air not treated with ozone, it is advisable that the ozone generator 6 turn on a little earlier and turn off a little later than the air pump 7. The delay depends on the manufacturer air pump 7 and can be from 1 to 10 seconds. This completes the preparation, and the water dispenser is ready for use.

During the operation of the dispenser, when the consumer presses the water dispensing button 17, the water valve 9 opens and the water flows through the water channel 12 of the finger 4 into the water pipe 8 and through the open water valve 9 and the nozzle 14 into the container for collecting water 15. At the same time by opening valve 9, the ozone generator 6 is turned on and, with a slight delay after the ozone generator 6, the air pump 7. The ozone generated by the ozone generator 6 is fed through the air pipe 5 to the air channel 11 of the finger 4, and from there into the bottle 3. In the bottle 3, the ozone passes through waters y and accumulates in the air cavity in the upper part of the bottle 3. After closing the water valve 9, the ozone generator 6 and the air pump 7 continue to work until the air pressure in the bottle 3 reaches a predetermined threshold. After reaching a predetermined threshold, the air pump 7 is turned off, and after some time after it, the ozone generator 6 is also turned off.

The frequency of water intake is determined only by the desire of the user. As long as there is water in bottle 3, water is dispensed to the consumer in the above mode. After emptying the bottle 3, the water supply stops, and it is necessary to replace the empty bottle with a full one.

When replacing the bottle 3, immediately before or at the time of removing the empty bottle 3, the ozone generator 6 and the air pump 7 are turned on, supplying ozone through the air pipe 5 to the intake finger 4 and through the air channel 11 of the intake finger 4 to the funnel 2, disinfecting or protecting from of infection, the air channel 11, the outer surface of the water intake finger 4 and the outer surface of the funnel 2. After installing a new full bottle 3 on the finger 4, the ozone generator 6 and the air pump 7 operate until the pressure inside the bottle 3 and air boprovoda 5 reaches a predetermined threshold.

The advantage of the proposed water dispenser is the ability to maintain a sterile air environment in the bottle for a long time and the sterilization of the water channel of the dispenser, which greatly simplifies and facilitates the maintenance of the dispenser in a satisfactory microbiological state in comparison with traditional solutions, due to the termination of constant regular preventive sanitary treatments, mandatory for conventional devices, without which satisfactory operation of such devices is not , suited.

The utility model can be used to supply drinking water in domestic and industrial premises. Especially in potentially dangerous, from the point of view of bacteriological contamination, public places with a large flow of people whose health status is not possible to control, where there is a risk of infection - such as hospitals, clinics, in places where children stay (kindergartens, schools) industrial premises with the difficulty of maintaining indoor air quality due to the specifics of production (carpentry shops, paint shops, hairdressers, kitchens, catering establishments, etc.), as well as on pre events where security is important (airport controller, police, military, medicine, nuclear plants, government agencies, sports facilities during competitions, etc.).

Claims (14)

1. A water dispenser for dispensing drinking water from an inverted bottle, comprising a housing, a funnel mounted on the outer surface of the housing for installing an inverted bottle neck down, a water finger installed on the bottom of the funnel, provided with separate air and water channels, characterized in that the water dispenser is further provided an ozone generator and an air pump connected by an air pipe to the air channel of the water finger, and is also equipped with a water pipe connected to the water channel waste diversion finger and equipped with a water valve. 2. The dispenser according to claim 1, wherein the air pump provides an overpressure in the bottle from 0.01 to 0.3 atm. 3. The dispenser according to claim 1 or 2, further comprising a flow-through cooling device included in the water pipe. 4. The dispenser according to claim 1 or 2, equipped with an electronic control device configured to control the operation of the pump and the ozone generator in accordance with the recorded program. 5. The dispenser according to claim 3, equipped with an electronic control device configured to control the operation of the pump, ozone generator, water valve and instantaneous water cooling device in accordance with the recorded program. 6. The dispenser according to claim 4, in which the electronic control device is configured to control the operation of the water valve. 7. The dispenser according to claim 4, in which the electronic control device is arranged to control the operation of the instantaneous water cooling device. 8. The dispenser according to claim 1 or 2, in which the water intake finger is provided with a bottle opening device. 9. The dispenser according to claim 1 or 2, equipped with an air valve installed in the air pipe. 10. The dispenser according to claim 9, in which the air pipe is made of ozone-resistant material. 11. The dispenser according to claim 1 or 2, equipped with a bottle presence sensor. 12. The dispenser according to claim 5, equipped with a bottle presence sensor. 13. The dispenser according to claim 1 or 2, equipped with an air pressure sensor in the air pipe. 14. The dispenser according to claim 5, equipped with an air pressure sensor in the air pipe.