RU209836U9 - AQUAVENDING MACHINE - Google Patents

Abstract

The utility model relates to aqua vending machines, in particular to water vending machines by means of automatically controlled dispensing of water into a water buyer's container. The technical problem lies in the need to reduce the power consumption during the operation of the aqua vending machine at negative ambient temperatures. The technical result consists in using the thermal energy of the water in the hydraulic accumulator to maintain a positive air temperature inside the body of the aqua vending apparatus during its operation at negative ambient temperatures. The device contains a thermally insulated housing 1, in which there is a reactor 4 for ultraviolet dynamic sterilization of drinking water, a fan 14 and means for preparing drinking water from tap water and dispensing drinking water into a container for a drinking water buyer. In turn, the reactor 4 includes a gravitational hydraulic accumulator 5 made of metal without thermal insulation and a source of ultraviolet radiation 6 located in it. the walls 2 and the male walls 7 form lateral gaps S for the passage of air pumped by the fan 14 to blow the housing of the gravitational accumulator 5 from its outer side. At the same time, the mentioned means for preparing drinking water from tap water and dispensing drinking water into the container of the buyer of drinking water are located above the reactor 4. 3 ill.

Description

Field of technology to which the utility model belongs

The utility model relates to aqua vending machines (water vending machines) designed to operate at negative ambient temperatures.

State of the art

Known vending machines for water (aqua vending machines) designed to operate at negative ambient temperatures through the use of climate control of the internal space of the vending machine (see, for example, the description of the utility model according to patent RU No. 113043 U1, IPC G07F 13/00, published on January 27, 2012, Bull. No. 3, patent holder V. V. Bakaleiko; description of the utility model according to patent RU No. 173506 U1, IPC G07F 13/00, published on August 29, 2017, Bull. No. 25, patent holder M. V. Reshetnikov).

The prototype is a kiosk-machine for the sale of water, which consists of an outer casing with thermal insulation, which has at least one vending machine, a heating and thermal control unit and at least one water tank (aquatic tank) with a drain from the overflow of the tank , water level sensors interconnected with the vending machine, an ozonation device associated with the water tank, and at the bottom of the water tank there is a drain that supplies water through the pump and the water purification device to the vending machine, as well as the filling unit, on the one hand having access to the tank, and on the other hand, a connection for filling the tank from an external source (patent RU No. 113043 U1, IPC G07F 13/00, published on January 27, 2012 Bull. No. 3).

Signs of a known device (prototype), coinciding with the signs of the claimed utility model, are that it contains a housing with a door that acts as the front panel of an aqua-vending apparatus, means for preparing drinking water from tap water and means for dispensing drinking water into a container located in this housing drinking water buyer.

The reason preventing the technical result obtained in the known device (prototype), which is provided by the claimed utility model, is that the heating of the internal space of the body of the aqua vending apparatus is carried out exclusively through the use of electricity, which makes the consumption of electricity significant in winter.

The technical problem to be solved by the utility model claimed for patenting is the need to reduce power consumption during operation of the aqua vending machine at negative ambient temperatures. Disclosure of the essence of the utility model

The technical result, mediating the solution of this technical problem, is to use the thermal energy of the water in the accumulator to maintain a positive air temperature inside the body of the aqua-vending apparatus during the operation of the aqua-vending apparatus at negative ambient temperatures, which leads to a decrease in electricity consumption during the operation of the aqua-vending apparatus at negative ambient temperatures.

The technical result is achieved by the fact that the aqua vending apparatus contains a thermally insulated housing with a door that acts as the front panel of the aqua vending apparatus, means for preparing drinking water from tap water and means for dispensing drinking water into the container of a drinking water buyer, located in this housing, as well as a fan installed in this housing and a reactor for ultraviolet dynamic sterilization of drinking water, including a gravitational hydraulic accumulator made of metal without thermal insulation, and a source of ultraviolet radiation located in it, while the fan is located with the possibility of blowing the gravitational accumulator from its outer side.

The technical result is also achieved by the fact that the mentioned gravitational accumulator is located below the means for preparing drinking water from tap water and dispensing drinking water into the container of the buyer of drinking water at a distance from the bottom of the aqua vending apparatus body, so that between the bottom of the aqua vending apparatus body and the plane of location of the bottom of the gravitational hydraulic accumulator is formed a functional space in which the specified fan is installed, while the side walls of the gravitational hydraulic accumulator are associated with the side walls of the aqua-vending apparatus housing enclosing them, so that side gaps are formed between the enclosing side walls of the aqua-vending apparatus housing and the male side walls of the gravitational hydraulic accumulator for the passage of air pumped by the specified fan for blowing through these gaps of the gravitational accumulator from its outer side.

Brief description of the drawings

In FIG. 1 is a schematic representation of a longitudinal (vertical) section of an aqua vending machine, showing only the aqua vending machine body, the reactor for ultraviolet dynamic sterilization of drinking water, and the fan; in fig. 2 is a view A-A in FIG. one; in fig. 3 is a schematic representation of said reactor.

Implementation of the utility model

The aqua vending apparatus contains a thermally insulated body 1 of the aqua vending apparatus, which is a hollow rectangular parallelepiped with four side walls 2 and a bottom 3. At the same time, one side wall 2 (side face) of the housing 1 is made in the form of a door that functions as the front panel of the aqua vending apparatus (the door in the figures not highlighted).

The aqua vending apparatus also contains a reactor 4 (Fig. 3) for ultraviolet dynamic sterilization of drinking water, which includes a gravitational accumulator 5 (water tower) made of metal without thermal insulation and located in its lower part (horizontally, as shown in Fig. 3, or vertically, as not shown in Fig. 3) a source of ultraviolet radiation 6. In this case, the gravitational accumulator 5 has four side walls 7, a bottom 8 located in a certain horizontal plane 9, an inlet pipe 10 located in the upper part of the accumulator 5, an outlet pipe 11, located in the lower part of the accumulator 5 in the zone 12 of the effective action of ultraviolet radiation from the source 6. The gravitational accumulator 5 divides the single working flow of water subject to ultraviolet dynamic sterilization in the reactor 4 into three successive sections of this stream: the inlet section of the stream, which is narrow in cross section (input pa tubes 10 and an external pipeline attached to it); the average wide section of the flow in cross section (actually the capacity of the gravitational accumulator 5); outlet narrow in cross-section section of the flow (outlet pipe 11 and an external pipeline attached to it). In this case, the source 6 of ultraviolet radiation is located in the region of the bottom 8 horizontally, as shown in FIG. 3, or vertically, as not shown in FIG. 3, and is characterized by the presence around this source during its operation of the zone 12 of the effective action of ultraviolet radiation, which is directly dependent on the power of the source 6. In addition, the bottom 8 is configured to provide the effect of a sudden narrowing of the working water flow when it flows through the outlet pipe 11, the inlet the opening of which is located in zone 12. This ensures that the maximum intensity of ultraviolet radiation is concentrated precisely on the maximum turbulent volume of water in the region of the bottom 8, which ensures both effective ultraviolet sterilization of the water in the accumulator 5 and efficient heat transfer from the source 6 to the water in the accumulator 5 , and from it to the walls of the accumulator 5, through which heat is transferred from this water to the air inside the case of the aqua-vending apparatus by blowing the fan 14 of the accumulator 5 from its outer side.

To improve the efficiency of this heat transfer, the reactor 4 (its gravitational accumulator 5) is located in the lower part of the housing 1 at a distance from the bottom 3, so that between the bottom 3 and the plane 9 of the bottom 8 of the accumulator 5, a functional space 13 is formed, in which the fan 14 is located with the possibility blowing the body of the gravitational accumulator 5 from its outer side. In addition, the hydraulic accumulator 5 is made and located so that its side walls 7 are associated with the side walls 2 of the housing 1 that enclose them, so that side gaps S are formed between the enclosing walls 2 and the male walls 7 for the passage of air pumped by the fan 14 to blow the gravity housing. hydraulic accumulator 5 from its outer side.

The concept of “clearance” is widely known in mechanical engineering: “A clearance in mechanical engineering is the distance between two surfaces of mating machine parts and other structures; is defined as the difference between the inner size of the female part and the outer size of the male part ”(see: Polytechnic Dictionary / Editorial: A.Yu. Ishlinsky (editor-in-chief) and others - 3rd ed., revised and additional - M .: Great Russian Encyclopedia, 2000. - S. 173).

In the context of the above definition in the claimed technical solution, the male part is the gravitational accumulator 5, taken in part of its side walls 7, and the female part is the body 1, taken in part of its side walls 2. The so-defined "gap" exhaustively indicates the possibility of passing through it air blown by the fan 14 from the functional space 13 into the gaps δ at a given speed for blowing the gravitational accumulator 5 from its outer side, namely such a speed that ensures optimal heat exchange of this air with the water in the accumulator 5 through its side walls 7 and its bottom eight.

In addition, the apparatus contains located in the upper part of the housing 1 (i.e. above the reactor 4) means for preparing drinking water from tap water (not shown) and means for dispensing drinking water into the container of the buyer of drinking water (not shown), suitably hydraulically connected with hydraulic accumulator 5.

The operation of the aqua vending apparatus is as follows.

Water from the water supply, which has a known positive temperature, passes through the means of purification, disinfection and conditioning of water (filters, membrane, etc.) and, becoming drinkable, enters the gravitational accumulator 5 through the branch pipe 10 and, under the influence of gravity, moves down and flows out of the gravitational accumulator 5 through the outlet pipe 11. At the same time, the gravitational accumulator 5 is initially filled with drinking water, after which the reactor 4 switches to a stationary mode of continuous water supply to the gravitational accumulator 5 and the continuous outflow of ultraviolet-treated water from it. In this case, the movement of water through the pipes 10 and 11 and the corresponding external pipes connected to these pipes (external pipes not shown) occurs at the same relatively high speed due to their equal flow sections (inlet narrow and outlet narrow sections of the flow). This speed provides a water flow rate of, for example, 10 liters per minute. However, water, entering through the pipe 10 into the gravitational accumulator 5 (middle wide section of the flow), in accordance with the law of continuity of the flow, significantly loses its speed inside the gravitational accumulator 5, since the flow area of the latter significantly exceeds the flow area of any branch pipe. So, for example, if the flow area of the gravitational accumulator 5 exceeds the flow area of the branch pipe by 10 times, then, accordingly, the speed of water movement inside the gravitational accumulator 5 is reduced by 10 times compared to the speed of water movement in the nozzles and external pipelines connected to them. Such a slowdown in the speed of water movement in the gravitational accumulator 5, due to the action of the law of continuity of the flow, increases the time spent by water in zone 12, and thereby contributes to its more effective sterilization and additional heating from the source 6. In addition, due to the above-mentioned excess of the flow area of the gravitational accumulator 5 and the execution of the bottom 8 of a flat (or close to flat) shape, the vertical lines of water flow inside the gravitational accumulator 5, approaching the bottom 8, are forced to sharply turn 90 ° towards the outlet pipe 11, thereby creating the effect of a sudden narrowing of the worker known in hydraulics flow. This effect creates flow turbulence in zone 12, and also creates vortices (whirlpools), which additionally and significantly increases the time spent by water in zone 12 and, accordingly, increases the efficiency of water sterilization and provides additional heating of water from source 6. This heating is due to the fact that that in the source 6 only a small part of the electrical energy is converted into the desired ultraviolet radiation. The other part of it is converted into thermal energy, which heats drinking water in reactor 5 in zone 12.

At the request of the buyer, drinking water is dispensed into the container of the buyer of water from the accumulator 5, which, at the command of the controller, is immediately replenished with new drinking water obtained from tap water (by purifying it), which has a positive temperature. Thus, in the accumulator 5 there is always drinking water, which is updated as it is sold and, as a result, always has a positive temperature due to the positive temperature of the tap water, additionally maintained by the source 6. In this case, the fan 14 is turned on when two conditions are met: the presence of water in hydraulic accumulator 5 and negative ambient temperature.

The fan 14 supplies air from the functional space 13 to the gap 3 on one side of the accumulator 5. This air passes through this gap and is heated by the water in the accumulator 5 through the corresponding wall 7 and rises to the upper part of the housing 1. There (above) the air temperature decreases and it, through the gap (or gaps) on the other side of the accumulator 5, descends into the lower part of the housing 1, passing through the gap, heats up from the water in the accumulator 5 through the corresponding wall 7 and enters the functional space 13 at the inlet of the fan 14 , thereby closing the cycle of circular movement of air inside the housing 1; at the same time, in the functional space 13, the air is heated from the water in the accumulator 5 through the bottom 8.

Such a maintenance of a positive air temperature only due to the thermal energy of the water in the accumulator 5, supplemented by heat from the source 6 of ultraviolet radiation, is possible at relatively low negative ambient temperatures (for example, down to -10°C). At a significantly lower ambient temperature (for example, -30°C), the indicated thermal energy will not be enough and then the controller, in addition to the main air heating system from the water of the accumulator 5, connects an additional air heating system using an electric heater installed in the functional space 13 on the flow line air from the fan 14. Under such circumstances, when excessively low negative temperatures are possible in the region of operation of the aqua vending machine, instead of the fan 14, it is necessary to immediately install a fan heater.

Thus, the use of the thermal energy of the water that is always in the accumulator 5 (energy supplemented by thermal energy from the source 6 of ultraviolet radiation located in the water of the accumulator 5) to heat the air inside the housing 1, in some cases completely eliminates the use of an electric heater, and in others in cases involving the use of an electric heater, reduces the operating time of this electric heater, which in any case allows you to significantly save energy during the operation of the aqua vending machine in winter.

Claims (2)

1. An aqua-vending apparatus, which contains a thermally insulated housing with a door that acts as the front panel of an aqua-vending apparatus, and means for preparing drinking water from tap water and dispensing drinking water into a container for a drinking water buyer located in this housing, characterized in that it contains a fan and a reactor for ultraviolet dynamic sterilization of drinking water, including a gravitational hydraulic accumulator made of metal without thermal insulation, and a source of ultraviolet radiation located in it, while the fan is located with the possibility of blowing the gravitational hydroaccumulator from its outer side. 2. The aqua vending apparatus according to claim 1, in which the gravitational accumulator is located below the means for preparing drinking water from tap water and dispensing drinking water into the container of the buyer of drinking water at a distance from the bottom of the aqua vending apparatus body, so that between the bottom of the aqua vending apparatus body and the plane of the bottom of the gravitational hydraulic accumulator, a functional space is formed in which the specified fan is installed, while the side walls of the gravitational hydraulic accumulator are associated with the side walls of the aqua-vending apparatus housing enclosing them, so that side gaps for the passage of air are formed between the enclosing side walls of the aqua-vending apparatus housing and the male side walls of the gravitational hydraulic accumulator, pumped by the specified fan for blowing through these gaps of the gravitational hydraulic accumulator from its outer side.

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