RU182420U1 - COOLER - Google Patents

Abstract

The utility model relates to devices for the dosed dispensing of melt water, hot and cold, and is intended for use at home, in offices, institutions and other public places. The cooler contains a hollow body, a thermally insulated container made in the form of a rectangular parallelepiped with a tapering bottom and a hinged lid. In a thermally insulated tank equipped with a cooling system, a stand with a heating element for an ice block is installed. A thermally insulated container is connected through a drain pipe to a storage tank. The storage tank is connected to the tanks of hot and chilled water. The cooling element is able to cool water to a temperature in the range from +3 to + 25 ° C, and the heating element can heat water to a temperature in the range from +25 to + 100 ° C. In an inclined, tapering bottom of a thermally insulated tank above the central drain pipe there is a drain hole associated with a reserve tank. The cooler is convenient in operation and creates a comfortable environment for the user. 8 s.p. f-ly, 3 ill.

Description

The utility model relates to devices for dosed dispensing of melt water, hot and cold, and is intended for use at home, in offices, institutions and other public places.

A known cooler comprising a lid with a seat for installing the neck of a container of water with a stopper in a lid cavity made of a cup-shaped shape with a side wall and a bottom, on which a needle is placed to pierce the membrane of the stopper of a container of water and supply water through an opening in the side wall of the needle to the valve water delivery systems (patent US 4629096, B67D 5/62, publ. 16.12.1986).

The disadvantage of this solution is that when the container is installed with a stopper on the neck in a lid that has a needle for piercing the stopper membrane, a sealed closed loop is formed in the cooler system, connecting the valve that opens the drain of water into the user's glass with the internal cavity of the container with water. As the pump is pumped out or self-flowing out under its own weight of water from the tank, the latter produces a lower pressure relative to atmospheric pressure, which, as the water decreases in the tank, deforms the walls of the tank and reduces the internal pressure in the system as a whole.

A known cooler comprising a lid with a seat socket for installing the neck of a water tank with a stopper in a lid cavity made of a cup-shaped shape with a side wall and a bottom, on which a sampling needle is placed for piercing the cork membrane or cap of a water tank and supplying water through an opening in the side wall intake needle to the valve of the water distribution system (RF patent 127737, B67D 1/00, publ. 05/10/2013). The apparatus is equipped with an air pumping system, consisting of an air compressor, through a non-return valve in communication with the air supply pipe, and a through hole is made in the needle along its longitudinal axis, with which the said pipe is connected to supply air into the container with water when opening the valve of the dispensing valve of the dispensing system water. The main feature of the device is the presence of a system for pumping air into the tank with water, which allows maintaining pressure in the tank and preventing deformation of the walls of the tank while reducing the volume of water contained in it. This decision was made as a prototype for the claimed facility.

The disadvantages of the prototype include the use as a sole source of water removable capacity, which significantly limits the operational capabilities of the device. Moreover, in case of depressurization of the drinking water bottle during transportation or operation (the formation of cracks or micro-holes through which atmospheric air can penetrate into the internal cavity of the water bottle), the pressure in the water bottle during operation decreases and, as a result, the water level in the nest for a water bottle is not supported. The water level rises and water through the air filter enters the internal cavity of the housing for electrical equipment, which can lead to a short circuit and fire. If this does not happen, for example, if the device is disconnected from the mains, then water flows to the table on which it is installed, or to the floor. A table with all the documents on it and the floor deteriorate. It is possible flooding below the floors of the house. As a result, the user suffers significant material damage.

The design of the prototype guarantees the consumer the portioned delivery of heated and chilled drinking water. But its drawback is the need to use water sources with initially high consumer characteristics (bottled water). A bottle is a source of bacteria and germs. Typically, such bottles are transported by truck when the bottles are open to ambient air. When unloading, the operator usually grabs the bottle by its neck, that is, by the part of the bottle that communicates with the open tank during use. Unfortunately, it is not possible to convince all bottle-unloading operators of the need to wash their hands as often as possible. In order to properly disinfect such a water dispenser or water cooler, the user must thoroughly clean the neck of the bottle before putting it into the cabinet. In addition, the user must from time to time flush water from the tank and disinfect it. Cleaning the tank in such a water distribution machine takes a lot of time and therefore it is not regularly carried out.

The basis of this utility model is the task of expanding the arsenal of technical means for the dosed dispensing of drinking hot and cold water and increasing the operational capabilities of the cooler.

The technical result of the achieved solution is the implementation of the claimed utility model of the indicated purpose, the creation of a water dispenser cooler, which provides melt drinking hot and cold water from the ice block.

The claimed technical result is achieved by the fact that a cooler is constructed comprising a housing in which a melt water tank with a lid and a tapering bottom is located, a melt water heating system, a melt water cooling system and a reserve tank, while a stand is fixed in the melt water tank, equipped with heating elements and designed to install an ice block to obtain melt water, and the melt water capacity is made communicating through the central drain pipe of the bottom with hot water tanks in the water heating system and chilled water in the water cooling system, and in the bottom of the tank above the Central drain pipe there is a drain hole associated with the reserve tank.

The device is complemented by private distinctive features that contribute to the achievement of the claimed technical result.

The capacity of melt water is thermally insulated.

A cooling system in the form of a fan is fixed on the melt water tank to prevent spontaneous melting of the ice block.

Hot and chilled water tanks are interconnected through a storage tank.

The elements for heating the stand are made in the form of a PETN spiral.

The heating elements of the stand are made in the form of an inductor.

A cooling coil is installed in the chilled melt water tank.

In the tank of hot melt water, a PETN spiral is installed.

The cover of the melt water tank is mounted on a hinge with the possibility of rotation through an angle of up to 270 °.

It is believed that tap water must be boiled to disinfect it. And it is right. But boiled water has its drawbacks. You can drink it only immediately after boiling - in the form of tea or coffee. During storage, it like a sponge absorbs various microorganisms, bacteria and viruses from the air. The constant use of boiled water can lead to urolithiasis.

Water obtained by freezing, for example, in a freezer, and then thawing ordinary (tap), or any other, is called melt water. Under natural conditions, melt water is formed as a result of melting snow and ice. It is known that during the preparation of melt water, the content of various impurities in it decreases, as well as the number of nuclei of the deuteron hydrogen isotope (D) present in water in the form of a chemical compound HDO - light heavy water molecules. Melt water with a low content of HDO molecules in it is often called protium (from the Latin Protium), i.e. containing mainly the nuclei of the light isotope of the hydrogen atom - H ⁺ (the proton or protium atom nucleus is from the Greek. protos - the first; in aqueous solutions, the proton hydrates and forms the compound H ₃ O ⁺ ). The indicated changes in the properties of melt water characterize it as better than the source water.

There is a way to get melt water at home - this is freezing, which is much more effective in terms of cleaning quality than boiling. Normal tap water is poured into a plastic bottle and placed in the freezer of the refrigerator (in winter it can be taken out to the balcony). First, ice is formed at the edges of the dishes, it is the purest water. Water with impurities freezes longer and collects in the center. When defrosting, clean ice can be separated from dirty ice. Water from pure ice - this is the necessary melt, healthy water. Meltwater has a life-giving effect on the body of both humans and plants. In a person who drinks 300-500 g of melt water daily, the activity of the heart, blood vessels of the brain and spinal cord is normalized, blood composition and muscle function improve. In people suffering from cardiovascular diseases, when taking melt water, a decrease in blood cholesterol is noted and the metabolism improves. It is also useful for people who have suffered injuries: bone fractures, ruptures of the ligaments of the joints, it is also useful for people who are obese.

The disadvantages of devices for producing melt water are inconvenient designs (pots or a plastic bottle from under drinking water), you have to use a complex and long-term method of preparing melt water, i.e. separating it from pure ice. Putting a pot or plastic bottle in the freezer of the refrigerator is possible, but inconvenient, because there are also products. In such primitive vessel designs, there are no details that make it possible to quickly and efficiently obtain melt water.

Known devices for water purification by freezing (RF patent 61704, C02F 1/22, publ. 10.03.2006), containing a vessel with upper and lower bottoms, an axial tubular heater and a power supply, while the working surface of the heater is made in the form of a perforated cylindrical shell with a deaf bottom and heat insulator, kinematically connected with the upper bottom, moreover, thermal protection is installed on the lower bottom of the vessel and a thin-walled elastic polyethylene fluoride bottle is used as the vessel. Work with such a device is as follows. Through a cylindrical shell, water is poured into the inside of the vessel, which is poured through its perforated holes inside the vessel. The water in the bottle and inside the shell is frozen, then it is defrosted using a heater. Through the perforated openings of the shell, thawed water enters the inside of the shell and is poured through the outlet of the shell.

The disadvantages of this solution of the device are: the structure is complex and ineffective, the shell is made in the form of a layer, tightening something, and after numerous perforated holes it is a very weakened structure, and a metal sleeve with a flange is fixed on it, i.e. unreliable part, it is inconvenient to insert the device together with the heater and the power supply unit into the refrigerator and it can be taken out of service during freezing, according to the image in the drawing, nothing is kinematically connected with the top of the bottle, defrosted water can pour out through the bottle neck earlier than through the outlet the shell hole, the design of the device during its manufacture is not technologically advanced and uneconomical, there is no possibility of draining dirty water, defrosted water is poorly cleaned with this technology and device structure.

The proposed utility model is schematically shown in the figures, which depict: in FIG. 1 is a front view of the cooler; FIG. 2 is a side view of the cooler, in FIG. 3 is a top view of the cooler.

The cooler comprises a hollow body 1, in the upper part of which there is a thermally insulated container 2, made in the form of a rectangular parallelepiped. The bottom of the tank 2 is made tapering downward, with the formation of a funnel in the center. In the upper part of the thermally insulated container 2, a thermally insulated, hinged cover 3 is pivotally rotated up to an angle of 270 °. The front part of the cover 3 is made in the form of a glass panel 4. The sides, bottom and lid of the thermally insulated container 2, in particular, can be insulated a layer of polystyrene or other eco-insulation.

The thermally insulated container 2 is equipped with a cooling system in the form of a fan 5, to prevent arbitrary melting of the ice block 6. The ice block 6 is mounted on a stand 7 mounted in a thermally insulated container 2 and having a heating element 8. The heating element 8 of the stand can be made in the form of a PETN spiral or inductor.

In the central part of the bottom of the thermally insulated tank 2 there is a drain pipe 9 connected to the storage tank 10. The storage tank 10 is connected to the tanks of hot 11 and chilled 12 water. All containers 10, 11, 12 are made communicating, while containers 11 and 12 are equipped with corresponding taps 13 and 14 for supplying water of the required temperature, located on the front side of the housing 1. The heating and cooling elements built into the tanks 11 and 12, respectively, can have a known design - cooling in the form of a coil, and heating in the form of a spiral. Moreover, the coil is capable of cooling water to a predetermined temperature in the range from +3 to + 25 ° C, and the heating element can heat water to a predetermined temperature in the range from +25 to + 100 ° C. In the inclined, tapering bottom of the thermally insulated container 2 above the central drain pipe 9 there is a drain hole 15 connected to the reserve tank 16. The device is operated as follows: Ice source 6 is prepared in advance or cut directly from a natural glacier, It is placed in a refrigerated, thermally insulated container 2. The ice block 6 is transported in a package that helps prevent pollution. The size of the ice block is recommended to be brought closer to the usual size of a bottle of water. A diameter of 0.27 m and a height of 0.37 m for a large block and, accordingly, a diameter of 0.27 m and a height of 0.185 m for a smaller block. Accordingly, the weight of 21 kg and 10.5 kg. It is also possible to use blocks with a sawn core, the diameter of which is 0.1 m. The masses of the blocks will respectively be 14 kg and 7 kg.

The cooling of the thermally insulated container 2 is carried out by the cooling system 5, to prevent arbitrary melting of the ice block 6. The ice block 6 is installed on the stand 7 and includes a heating element 8. The material of the stand is metal alloys or ceramics. There is a heating stand 7, which heats the ice block 6, which allows you to convert water from solid to liquid. The water obtained from the heating flows through the sides of the stand 7. Then the water, through the drain pipe 9, gets the storage tank 10. From the storage tank 10, the water enters the heated tank with a heating element 11 and a cooled tank, with a cooling element 12. Water temperature support sensors that periodically start the operation of cooling and heating systems. Due to this, the cooler always contains some - depending on the capacity of the containers - the amount of cold and hot water. Through taps 13, 14, hot or chilled water is supplied directly to the consumer. In the event of a power outage, spontaneous melting of the ice block 6 is possible. In this case, water is poured into the reserve tank 16 through the drain hole 15. Ice blocks can be replaced by simply installing the block on the block or in place of the used block. Since the cover 3 is fixed on a hinge with the possibility of deviation by 270 °, the block 6 can be placed both on top and in front.

For the consumer, obtaining melt water occurs as follows. The consumer presses the "Start" key. A current flows through the electric circuit to the heating element 8 of the stand 7. The lower part of the ice block begins to melt and water overflows through the sides of the stand 7. The person pours the water into the glass, opening the corresponding hot or cold water, tap 13 or 14. The process is visible through the glass panel 4.

This utility model is industrially applicable and can be manufactured using well-known technologies for the manufacture of machines such as coolers.

The proposed utility model is compact, simple and quite convenient to operate, creating comfortable conditions for the user in various offices and can be used to obtain clean portioned melt water.

Claims (9)

1. A cooler comprising a housing in which a melt water tank with a lid and a bottom tapering to the bottom, a melt water heating system, a melt water cooling system and a reserve tank are located, wherein a stand provided with heating elements and designed for installation of an ice block to obtain melt water, and the melt water tank is made in communication through the central drain pipe of the bottom with hot water tanks in the water heating system and chilled water in the water cooling system, and in the tank bottom above the central drain pipe there is a drain hole associated with the reserve tank. 2. The cooler according to claim 1, characterized in that the melt water tank is thermally insulated. 3. The cooler according to claim 1, characterized in that a cooling system in the form of a fan is fixed to the melt water tank to prevent spontaneous melting of the ice block. 4. The cooler according to claim 1, characterized in that the containers of hot and chilled water are interconnected through a storage tank. 5. The cooler according to claim 1, characterized in that the heating elements of the stand are made in the form of a PETN spiral. 6. The cooler according to claim 1, characterized in that the heating elements of the stand are made in the form of an inductor. 7. The cooler according to claim 1, characterized in that a cooling coil is installed in the chilled melt water tank. 8. The cooler according to claim 1, characterized in that a ten PET spiral is installed in the hot melt water tank. 9. The cooler according to claim 1, characterized in that the lid of the melt water tank is fixed on a hinge with the possibility of rotation through an angle of up to 270 °.

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