RU2795668C1 - Split system for water vending - Google Patents

Abstract

FIELD: vending machines.

SUBSTANCE: invention is related to street water vending in winter, carried out by preparing and selling drinking water obtained from ordinary tap water by cleaning and processing it. The patented technical solution is a split system for such water vending, including an indoor unit located in an insulated room and an outdoor unit located outside the insulated room with the ability to operate at low temperatures. The technical problem lies in the need to expand the arsenal of technical equipment for outdoor water vending in winter, which must be characterized by high reliability in winter at low temperatures, relatively lower power consumption, and a relatively simpler design. The split system comprises indoor unit 1 located in insulated room 2, outdoor unit 3 located outside of the room on wall 10 from its outer side. The blocks are hydraulically interconnected by means of supply pipeline 4 passing through opening 11 in wall 10. The indoor unit 1 includes preparation module 5, dynamic hydraulic accumulator 6 and feed pump 7. External block 3 is made in form of a wall cabinet and includes filling chamber 8 with branch pipe 9, water vending control and a means of paying for the purchase of drinking water. The outer section of pipeline 4, limited on one side by opening 11, and on the other side by branch pipe 9, is provided with means of thermal insulation and electrical heating. In addition, this outer section has a length less than the length of the entire pipeline 4, and branch pipe 9 is located above the maximum possible water level in dynamic accumulator 6. Filling chamber 8 also contains unit for collecting overflowing water 12 and draining it through discharge pipeline 13 into sewer pipe 14. Conduit 13 passes through opening 11 in wall 10 located below unit for collecting overflowing water 12. The outer section of pipeline 13, limited on one side by opening 11 in wall 10, and on the other hand by unit for collecting overflowed water 12, and unit 12 itself are equipped with means for their thermal insulation and electrical heating.

EFFECT: fulfillment of the specified purpose

5 cl, 5 dwg

Description

The field of technology to which the invention belongs

The invention relates to street aqua vending in winter, carried out by preparing and selling drinking water obtained from ordinary tap water by cleaning and processing it. At the same time, the technical solution claimed for patenting is a split system for this aqua vending, including an indoor unit located in an insulated room and an outdoor unit located outside the insulated room with the ability to operate at low temperatures.

State of the art

Known street terminal for aqua vending, containing hydraulically connected with the centralized water supply and centralized sewage module for obtaining drinking water from the water of the centralized water supply, hydraulically connected to it the module for pouring drinking water, a control module, a buffer tank with the function of ultraviolet disinfection of drinking water, hydraulically connected between the output of the specified module for obtaining drinking water and the input of the module for pouring drinking water, as well as the wall cabinet, in which the module for pouring drinking water and the control module are located, while the wall cabinet is attached to the wall of the building from its outer side, and at least one opening for pipelines through which a pipeline passes, hydraulically connecting the outlet pipe of the buffer tank with the inlet of the module for filling drinking water, while pipelines pass through the specified hole or holes, namely, the pipeline hydraulically connecting the inlet pipe of the buffer tank with the outlet of the specified module for obtaining drinking water water, and pipelines hydraulically connecting the specified module for obtaining drinking water with the centralized water supply and centralized sewerage, while the specified module for obtaining drinking water is located in a wall cabinet, and the buffer tank is located on the other side of the building wall (Patent RU No. 2764878 C1, IPC: C07F 13/00, published: 01/21/2022 Bull. No. 3, author and patent holder: Vyatkin V.V.).

The features of the well-known outdoor terminal for aqua vending, which are common with the features of the split system claimed for patenting, are that it contains a wall cabinet in which a drinking water bottling module and a control module are located, while the wall cabinet is attached to the wall of the building from its outer side and in the wall of the building there is at least one opening for pipelines, through which a pipeline passes, hydraulically connecting the outlet pipe of the buffer tank with the inlet of the drinking water filling module, and the buffer tank is located on the other side of the building wall.

The reason that prevents the technical result obtained in the well-known street terminal for aqua vending, which is provided by the technical solution claimed for patenting (split system), is that the said module for obtaining drinking water from the water of the centralized water supply pipeline is located in a wall cabinet, which requires the provision of all a wall cabinet with thermal insulation and electric heating in winter, which in turn requires significant energy costs and complicates the system.

A device for selling water is known, taken as a prototype and actually representing a split system for aqua vending, which has an all-weather and anti-vandal design and which contains two interconnected blocks, one of which is a block for the preparation, supply and storage of drinking water, located in an insulated room , and the other is a water bottling unit made of durable metal with a fitting and an electronic control and payment device, while the units are hydraulically connected to each other using a water pipe, which is made insulated (thermally insulated) and equipped with a thermo-releasing element located along the pipe, for example, a “heating tape "(Patent RU No. 96652 U1, IPC: G01F 1/00, published: 10.08.2010 Bull. No. 22, author and patent holder: Bakaleyko V.V.).

The features of the well-known split system for aqua vending (prototype), which are common with the features of the split system for aqua vending claimed for patenting, are that the known system contains an indoor unit located in an insulated room, an outdoor unit located outside the insulated room, a supply pipeline, hydraulically connecting these blocks and designed to supply drinking water to the buyer of water, as well as means of thermal insulation and electrical heating, while the indoor unit contains a preparation module designed to prepare drinking water from centralized water supply, a drinking water storage module and a module for supplying drinking water to the buyer's container water, and the external unit contains a filling chamber designed for pouring water into the container of the water buyer and containing a branch pipe for direct dispensing of water into the container of the water buyer, which is connected to the supply pipeline, also the external unit (3) contains aqua vending control and a means of paying for the purchase of drinking water.

The reason that prevents obtaining in the known split system for aqua vending (prototype) the technical result, which is provided by the split system for aqua vending claimed for patenting, is that in it (the known system) the mentioned supply pipeline throughout its entire length is outside the insulated room , as a result of which in winter it is exposed to negative temperatures throughout its entire length, which requires the use of its (pipeline) thermal insulation and electrical heating. This increases the consumption of electricity in the winter time of operation of the system, reduces the reliability of the system, and complicates its design.

The technical problem, which the split system claimed for patenting is aimed at, is to expand the arsenal of technical means of outdoor aqua vending in winter, characterized by high reliability in winter at low temperatures, relatively lower power consumption, relatively simpler design.

Disclosure of the essence of the invention

The technical result, mediating the solution of this technical problem, consists in the implementation of the specified purpose due to the preparation and dynamic accumulation of drinking water completely in an insulated room, as well as due to the transportation of this water through the water supply pipeline, also almost completely (at least 90%) within insulated room, so that even in the event of an emergency power outage, the system will not be defrosted. This increases the reliability of the system operation in winter, simplifies the design of the system due to the exclusion of a significant part of the thermal insulation and electrical heating means from the design, for the same reason, there is a decrease in electricity consumption in winter. In addition, in the process of aqua vending, water often overflows, which must be diverted into the sewer. Without solving this issue, the reliability of the system operation in winter is significantly reduced, since frozen overflowing water greatly complicates the process of aqua vending. To do this, in the claimed system, means are provided for collecting and diverting overflowed water into the sewer (positions 12, 13, 14 in Fig. 1-4), which are made in such a way that the possibility of formation of a water seal in these means that can freeze is excluded.

The technical result is achieved by the fact that the split system claimed for patenting contains an internal unit 1 located in an insulated room 2, an external unit 3 located outside the insulated room 2, a supply pipeline 4 hydraulically connecting these blocks and designed to supply drinking water to the buyer of water, as well as means of thermal insulation and electrical heating, while the indoor unit 1 contains a preparation module 5 designed to prepare drinking water from centralized water supply, a means of storing and supplying drinking water to the container of the water buyer, and the external unit 3 contains a filling chamber 8 intended for filling water into the container of the water buyer and containing a branch pipe 9 for direct dispensing of water into the container of the water buyer, which is connected to the supply pipeline 4, the external unit 3 also contains a water vending control and a means of paying for the purchase of drinking water, while the drinking water storage means is a dynamic hydraulic accumulator 6, hydraulically connected to the specified preparation module 5 and designed for dynamic accumulation of drinking water with simultaneous ultraviolet sterilization of this dynamically accumulated water, the drinking water supply means is a supply pump 7 designed to supply drinking water to the buyer of water from the dynamic accumulator 6 through the supply pipeline 4 , and the outer block 3 is made in the form of a wall cabinet, in which the listed devices that are part of this block are located, while this wall cabinet of the block 3 is fixed on the wall 10 of the insulated room 2 on the outside of this wall, in which a hole 11 is made , designed to pass through it the supply pipeline 4, which passes through this hole 11, so that the outer section of the supply pipeline 4, limited on the one hand by the hole 11, and on the other hand by the specified branch pipe 9, located above the maximum possible water level in the dynamic hydraulic accumulator 6 , is equipped with means of thermal insulation and electrical heating of this outer segment, which at the same time has a length less than the length of the entire supply pipeline 4, and the filling chamber 8 in the region of its bottom contains a means 12 for collecting overflowed water, to which the discharge pipeline 13 is hydraulically connected, designed to drain of this overflowing water into the sewer pipe 14 located inside the insulated room 2, while the discharge pipeline 13 passes either through the same hole 11 in the wall 10 as the supply pipeline 4, or an additional hole is made in the wall 10 through which the discharge pipeline 13 passes so that any hole in the wall 10 through which the outlet pipe 13 passes is located below the means 12 for collecting overflowed water, while the outer section of the outlet pipe 13, bounded on one side by the hole 11 in the wall 10 or another corresponding hole in the wall 10, through which passes the discharge pipeline 13, and on the other hand, a means 12 for collecting overflowed water, and this means 12 itself is equipped with means for their thermal insulation and electrical heating.

The technical result is also achieved by the fact that the system contains a valve 15 installed on the supply pipeline 4, while the specified valve is either a check valve or an electromagnetically controlled valve.

The technical result is also achieved by the fact that the wall cabinet of the outdoor unit 3 is installed at a distance from the zero level 16 of the insulated room 2.

- образный сегмент этого колена гидравлически соединен с динамическим гидроаккумулятором 6 через патрубок в днище этого гидроаккумулятора, либо в виде горизонтально ориентированного отрезка, входной конец которого гидравлически соединен с динамическим гидроаккумулятором 6 через патрубок в нижней части боковой стенки этого гидроаккумулятора, при этом подающий насос 7 выполнен в виде погружного центробежного насоса с «мокрым» ротором и расположен либо в нижней части указанного U-образного колена трубопровода подачи 4, либо в указанном горизонтально ориентированном отрезке трубопровода подачи 4.The technical result is also achieved by the fact that the lower part of the supply pipeline 4 is made either in the form of a U-shaped elbow, so that the inlet

- the figurative segment of this knee is hydraulically connected to the dynamic accumulator 6 through a pipe in the bottom of this accumulator, or in the form of a horizontally oriented segment, the input end of which is hydraulically connected to the dynamic accumulator 6 through a pipe in the lower part of the side wall of this accumulator, while the supply pump 7 is made in the form of a submersible centrifugal pump with a "wet" rotor and is located either in the lower part of the specified U-shaped bend of the supply pipeline 4, or in the specified horizontally oriented segment of the supply pipeline 4.

The technical result is also achieved by the fact that the opening 11 is located either within the area of the conditional rectangle specified by the inner perimeter and facing the wall 10 of the wall cabinet of the external unit 3, or between the specified conditional rectangle and the zero level 16 of the insulated room 2. A brief description of the drawings

In FIG. 1 shows a diagram of the first version of the claimed split system for aqua vending, characterized by the execution of the lower part of the supply pipeline 4 in the form of a U-shaped elbow and the location of the hole 11 in the wall 10 within the area of the conditional rectangle specified by the inner perimeter of the wall cabinet of the outdoor unit (3); in fig. 2 shows a diagram of the second version of the claimed split system for aqua vending, characterized by the execution of the lower part of the supply pipeline 4 in the form of a horizontally oriented segment and the location of the hole 11 in the wall 10 within the area of the conditional rectangle specified by the inner perimeter of the wall cabinet of the outdoor unit 3; in fig. 3 shows a diagram of the third version of the claimed split-system for aqua vending, characterized by the execution of the lower part of the supply pipeline 4 in the form of a U-shaped bend and the location of the hole 11 in the wall 10 between the specified conditional rectangle and the zero level 16 of the insulated room 2; in fig. 4 shows a diagram of the fourth version of the claimed split system for aqua vending, characterized by the execution of the lower part of the supply pipeline 4 in the form of a horizontally oriented segment and the location of the hole 11 in the wall 10 between the specified conditional rectangle and the zero level 16 of the insulated room 2; in fig. 5 shows a functional diagram reflecting the structure of the indoor unit 1 of the split system.

Implementation of the invention

The split system for aqua vending contains an indoor unit 1 located in an insulated room 2, and an outdoor unit 3 located outside this room on the wall 10 of this room from its outer side. Moreover, these blocks are hydraulically interconnected by means of a supply pipeline 4 passing through an opening 11 in the wall 10 (Fig. 1-4).

The indoor unit 1 includes a preparation module 5 located in an insulated room 2, designed for preparing drinking water from centralized water supply, an associated dynamic accumulator 6, designed for dynamic accumulation of drinking water in connection with the issuance of this water to the water buyer, and a supply pump 7, designed to supply drinking water to the buyer of water from the specified accumulator 6 through the supply pipeline 4 to the filling chamber 8 of the external unit 3 (Fig. 1-4).

The dynamic hydraulic accumulator 6 is a container of a relatively small volume, in the upper part of which there is an inlet pipe hydraulically connected to the output of the preparation module 5, and in the lower part there is an outlet pipe hydraulically connected to the pump inlet 7 (nozzles are not shown in the figures). In this case, the outlet pipe is installed either in the bottom of the tank or in the side wall of the tank. The function of this hydraulic accumulator 6 is to constantly maintain an operational reserve of drinking water in order to ensure a dynamic balance between, on the one hand, the dynamically acceptable flow of water into the container of the water buyer, and on the other hand, the actually limited dynamic capabilities of the centralized water supply pipeline and the reverse osmosis membrane 25, since always in aqua vending, the consumption of drinking water in the container of the water buyer exceeds the productivity of the centralized water supply pipeline and the productivity of the membrane 25 of the preparation module 5. This discrepancy is due to two reasons. Firstly, on the one hand, the consumption of drinking water in the process of dispensing it into the container of the water buyer should be such that the time of this dispensing is psychologically acceptable for the buyer (for example, 30 seconds, since he does not want to wait longer). Secondly, on the other hand, the centralized water supply pipeline has known flow limitations, and the reverse osmosis membrane 25 from this pipeline takes only 30% as permeate. And thirdly, the reverse osmosis membrane 25 itself, taken at an affordable price, is not characterized by great potential for its performance. And then the problem is solved by the specified operational reserve of the dynamic accumulator 6 in combination with interruptions in the release of water into the containers of water buyers, so that whenever the pump 7 is turned on, the capacity of the accumulator 6 is simultaneously replenished, and this replenishment is carried out for as long as pump 7 is turned on, and a little further until the specified operating reserve is fully restored.

In addition, inside the dynamic accumulator 6 there is an ultraviolet lamp in a protective case made of a material that transmits ultraviolet radiation, which is installed horizontally or vertically, and so that the inlet of the outlet pipe of the dynamic accumulator 6 is located in the zone of the disinfecting effect of this lamp (the pipe and the lamp are not marked ). Thus, the dynamic accumulator 6, on the one hand, makes it possible to create an operational reserve of drinking water during aqua vending (due to the systematic excess of water flow from it into the filling chamber 8 over the flow rate of water entering it from module 5) and use this reserve for issuance of drinking water into the container of the water buyer, thereby reducing the requirements for the membrane 25 and even possibly excluding the use of the pump 23 at the inlet of this membrane, which simplifies the design (Fig. 5), and on the other hand, in the dynamic accumulator 6 at the outlet of it (before its outlet) in the process of issuing water into the container of the water buyer, the effect of a sudden narrowing of the flow of this water takes place, which creates a significant turbulence in the flow of this water in the area of the zone of bactericidal action of the ultraviolet lamp, thereby increasing the effectiveness of its (lamp) disinfecting action in the process of issuing water to the container of the buyer of water, which increases the reliability of the issuance of high quality water.

The external unit 3 is made in the form of a metal wall cabinet (position "3" also indicates the cabinet) installed on the wall 10 of the insulated room 2 on its (walls) outer side and includes a filling chamber 8 located in this cabinet, aqua vending control (not shown ) and a means of payment for the purchase of drinking water (not shown).

In the preferred embodiment of the split system, the cabinet of the outdoor unit 3 is installed at a distance from the zero level 16 of the insulated room 2, as shown in Fig. 1-4. Such an arrangement of the cabinet, when it does not actually occupy a land plot of zero level 16, allows the system owner to save on the lease of a land plot, which would have to be rented if the wall cabinet is installed not at the specified distance, but directly on the ground. However, it is also possible that the cabinet, being attached to the wall 10, at the same time directly rests on the surface of the zero level 16 (i.e., on the ground), which can be justified by the low strength properties of the wall 10.

As for the hole 11, it can be made in the wall 10 both within the area of the conditional rectangle given by the inner perimeter of the wall cabinet of the external unit 3 facing the wall 10 (Fig. 1, 2), and between the specified conditional rectangle and the zero level 16 of the insulated room 2 (Fig. 3, 4). The first arrangement of the opening 11 shown in FIG. 1 and 2 is more preferable from the point of view of increasing the reliability of the split system, since pipelines 4 and 13 are hidden from an external observer, which makes them vandal-proof. It (this first option) is the only one if the cabinet of the outdoor unit 3 is installed on the wall 10 resting on the ground (zero level 16). As for the second variant of the location of the hole 11 (Fig. 3 and 4), it is possible, but its conditionality is not obvious.

The filling chamber 8 is intended for pouring water into the container of the water buyer and contains a branch pipe 9 in its upper part, and a means 12 for collecting overflowed water in its lower part. At the same time, the branch pipe 9 is hydraulically connected to the outlet end of the supply pipeline 4, is intended for direct delivery of water into the container of the water buyer and is located above the maximum possible water level in the dynamic accumulator 6 in order to exclude the possibility of spontaneous outflow of water from the dynamic accumulator 6, since this should only be forced with the help of pump 7, since only a forced supply of water provides an acceptable for the buyer of water, a fairly short time for supplying water to him in his container, as well as the accuracy of dosing necessary for the sale and purchase. Thus, the specified location of the nozzle 9 above the maximum possible water level in the dynamic accumulator 6 increases the reliability of the system by eliminating the possibility of spontaneous outflow of water from the specified accumulator 6.

The supply pipeline 4, which hydraulically connects the outlet pipe of the dynamic hydraulic accumulator 6 (the pipe is not shown) with the said pipe 9 of the filling chamber 8, passes through the hole 11 made in the wall 10 of the insulated room 2. The outer (upper) segment of this pipeline 4, limited on one side opening 11, and on the other hand, the indicated branch pipe 9 of the loading chamber 8, is equipped with means of thermal insulation and electrical heating, and at the same time has a length that is less than the length of the entire supply pipeline 4 (and much less, for example, ten or more times). This directly and directly implies a lower consumption of electricity for heating the pipeline 4, as well as the relative simplicity of the system and its higher reliability due to the reduction of thermal insulation and electrical heating of the supply pipeline 4.

In addition, a valve 15 (Fig. 1-4) can be installed on the supply pipeline 4, although not necessarily, a valve 15 (Fig. 1-4), which is either a check valve or an electromagnetic controlled valve that prevents the reverse movement of water into the dynamic accumulator 6. In this case, split - the system is equally efficient both in the presence of valve 15 and in its absence. The difference is that in the absence of valve 15, after the end of the delivery of water to the next water buyer, the water remaining in the pipeline 4 flows back into the dynamic accumulator 6 according to the law of communicating vessels, and for this reason, an air cushion appears in the pipeline 4 above the water level in the dynamic accumulator 6. And then, when the water is again issued from the dynamic accumulator 6 to another (next) water buyer, this new water first displaces air from the pipeline 4 and only then enters the other water buyer. Thus, there is some delay in dispensing water to another (next) water buyer, and possibly so small that it can be abstracted from (≈ 2 seconds). But it (the delay) can be more significant if the pipeline 4 has a significant overall length, and it will be difficult to abstract from such a delay. If the system contains a valve 15, then it will prevent the specified flow of water into the dynamic accumulator 6 from the pipeline 4, as a result of which there will always be water in the pipeline 4, and there will be no air cushion. Under such circumstances, there will be no said delay.

-образный сегмент этого колена гидравлически соединен с динамическим гидроаккумулятором 6 через патрубок в днище этого гидроаккумулятора. По второму варианту указанная нижняя часть выполнена в виде горизонтально ориентированного отрезка, как показано на фиг. 2, 4, входной (левый по рисунку) конец которого гидравлически соединен с динамическим гидроаккумулятором 6 через патрубок в нижней части боковой стенки этого гидроаккумулятора. При этом подающий насос 7 в предпочтительном варианте выполнения системы представляет собой погружной центробежный насос с «мокрым» ротором и низковольтным электроприводом постоянного тока (что обеспечивает безопасность эксплуатации системы), и он расположен либо в нижней части указанного U-образного колена трубопровода подачи 4, либо в указанном горизонтально ориентированном отрезке трубопровода подачи 4. В любом варианте он (насос) всегда будет находиться в воде благодаря форме нижней части трубопровода 4, что обеспечит его (насоса) постоянную готовность к работе.In addition, the lower part of the supply pipeline 4 has two versions. According to the first variant, said lower part is made in the form of a U-shaped elbow, as shown in FIG. 1, 3, so the input (left in the figure)

-shaped segment of this knee is hydraulically connected to the dynamic hydraulic accumulator 6 through a branch pipe in the bottom of this accumulator. According to the second variant, said lower part is made in the form of a horizontally oriented segment, as shown in Fig. 2, 4, the input (left in the figure) end of which is hydraulically connected to the dynamic accumulator 6 through a pipe in the lower part of the side wall of this accumulator. At the same time, the feed pump 7 in the preferred embodiment of the system is a submersible centrifugal pump with a "wet" rotor and a low-voltage DC electric drive (which ensures the safety of the system operation), and it is located either in the lower part of the specified U-shaped bend of the supply pipeline 4, or in the indicated horizontally oriented section of the supply pipeline 4. In any case, it (the pump) will always be in the water due to the shape of the lower part of the pipeline 4, which will ensure its (pump) constant readiness for operation.

The filling chamber 8 also contains a means 12 located in the area of its bottom for collecting overflowed water in the process of dispensing water into the container of the buyer of water, which is a kind of container or funnel and which, through the discharge pipeline 13, is hydraulically connected to the sewer pipe 14 of the centralized system located in the insulated room 2 sewerage waste. In this case, the outlet pipeline 13 in the preferred embodiment of the invention passes through the same hole 11 in the wall 10 as the supply pipeline 4. However, a separate additional hole for the pipeline 13 (not shown) can be made in the wall 10, through which the outlet pipeline 13 passes. , and so that any of these holes (either the hole 11 or the specified additional hole in the wall 10) is located below the overflow water collection means 12 in order to prevent the formation of a stagnation of overflow water in the discharge pipeline 13. In addition, the outer section of the outlet pipeline 13, limited on one side by a hole 11 in the wall 10 (or other corresponding hole in the wall 10 through which the outlet pipeline 13 passes), and on the other side by a means 12 for collecting overflowed water, and this means 12 itself equipped with means for their thermal insulation and electrical heating due to the fact that the specified outer segment and means 12 in winter are constantly in the zone of negative temperatures.

In addition, the filling chamber 8 in the preferred embodiment also has a door made of light-transmitting plastic (not shown).

In addition, the external unit 3 also includes a controlled ozone generator connected to the loading chamber 8 and an automatic supply of this ozone (not shown) designed for ozone disinfection of the water buyer's container before supplying water purchased by the water buyer to this container.

The indoor unit 1 of the split system for aqua vending contains (Fig. 5) a drinking water preparation module 5, a dynamic hydraulic accumulator 6 and a pump 7 located in the lower part of the supply pipeline 4.

Module 5 contains a filter assembly 17 hydraulically connected in series for filtering water taken from a centralized water supply, a membrane assembly 18 for separating filtered water into permeate and concentrate, and a modifying assembly 19 for permeate modification (Fig. 5).

The filter assembly 17 contains a coarse mechanical filter 20 hydraulically connected in series, made of foamed polypropylene with a pore size of, for example, 5 microns, a sorption filter 21 made of coal, and a fine mechanical filter 22, made of foamed polypropylene with a pore size of e.g. 1 micron. At the same time, the inlet of the filter unit 17 (it is also the inlet of the filter 20, it is also the inlet of the module 5) is hydraulically connected to the centralized water supply pipeline.

Membrane assembly 18 contains a pump 23 to increase the pressure at the inlet of the membrane 25 (in this case, this pump may not be used at a sufficient level of pressure in the centralized water supply), an electrically controlled shut-off valve 24, a reverse osmosis membrane 25 with a permeate outlet 26 and a concentrate outlet 27, controlled by a hydraulic resistance 28, a shut-off electrically controlled valve 29, as well as a branch pipe 30 for draining the concentrate, which is hydraulically connected to the sewer pipe 14.

The pump 23 is designed to create, if necessary, additional pressure at the inlet of the membrane 25. It is a diaphragm (diaphragm) pump with a low-voltage DC electric drive. Such a pump is able to create significant pressure at a relatively low flow rate, which is essential for a reverse osmosis membrane used in aqua vending. A feature of the operation of such a pump is the risk of overheating during prolonged continuous operation. In order to exclude the possibility of overheating, the pump 23 is equipped with a temperature sensor and an on-off controller set to two temperatures: the pump shutdown temperature (for example, 50 °C), upon reaching which the pump automatically turns off, and the pump switch-on temperature (for example, 40 °C). °), below which the pump automatically restarts.

The valve 24 is designed to be controlled by the controller on and off the process of supplying water to the dynamic hydraulic accumulator 6. The hydraulic resistance 28 is designed for a given distribution of permeate and concentrate flows. The valve 29 is intended for periodic flushing of the membrane 25 in order to increase the time of its effective operation (washing occurs when the controller, in accordance with the maintenance program for the membrane 25, opens the valve 29 for a predetermined time).

The modifying unit 19 contains, for example, a device 31 for adjusting the mineral composition of the permeate, a device 32 for adjusting the organoleptic properties of the permeate, and a device 33 for adjusting the pH of the permeate, hydraulically interconnected in series. At the same time, the output of the modifying unit 19 (it is also the output of the module 5) is hydraulically connected to the input of the dynamic hydraulic accumulator 6.

The dynamic hydraulic accumulator 6 contains a source of ultraviolet radiation (not marked with a position), which is located in this accumulator near its outlet. Drinking water, prepared by the devices of module 5, enters the dynamic hydraulic accumulator 6 (moreover, it enters when the actual water level in it is lower than the maximum possible water level in it), where it is temporarily accumulated (storage) and permanently disinfected by ultraviolet light, regardless of the issuance of water pump 7 from this accumulator to water buyers. In this case, the pump 7 (water supply means) is located in the lower part of the pipeline 4, since this pump (water supply means) uses a submersible centrifugal pump with a “wet” rotor, which is characterized by a low, and therefore safe supply voltage of its DC electric drive. And for such a pump to ensure its uninterrupted operation, as you know, it is necessary to always be in the water, which is what the U-shaped shape provides. This further simplifies the system and increases its reliability, as well as increases its safety through the use of a low voltage (and therefore safe) power supply to the pump 7.

The control and payment module (not shown) belongs to block 3 and is located in the wall cabinet on wall 10, and some of its (module) devices are installed on the front panel of the wall cabinet for access to them by the water buyer. At the same time, this module includes a controller, control buttons, a display, payment acceptance tools and other necessary user interface devices.

The functioning of the split system for aqua vending is as follows.

The supply of water from the preparation module 5 to the dynamic accumulator 6 is determined only by the actual water level in this accumulator and is aimed at maintaining the equality of the actual water level in it to the maximum possible water level in it.

In the initial state of the system, when the system is already ready for the sale of water, but there is no sale yet, the dynamic accumulator 6 is filled with completely potable water, which is under the constant action of disinfecting ultraviolet radiation. At the moment when a request is received from the buyer of water to issue the water he purchased, the controller first turns on the ozone generator for a specified time (for example, 10 seconds), as a result of which, during this time, ozone enters the buyer's container and thereby disinfects the internal space of this containers. After that, using the pump 7, water is supplied from the dynamic accumulator 6 to the filling chamber 8 and, accordingly, to the container of the water buyer. As a result, the water level in the dynamic accumulator 6 begins to decrease, as a result of which the operation of the module 5 automatically starts and, simultaneously with the release of water from the accumulator 6, new water enters it from the module 5 to compensate for the flow from it. At the same time, the operation of the module 5 occurs both during the entire period of dispensing water to the buyer of water, and for some time after this dispensing until the actual water level in the accumulator 6 reaches the maximum possible level. This cycle is then repeated for the new customer.

The work of the preparation module 5 is as follows. The water of the centralized water supply pipeline, which is always under pressure in this pipeline, under the influence of the specified pressure enters the inlet of the filter unit 17 (i.e., at the inlet of module 5), where it undergoes three stages of purification: coarse purification from mechanical impurities by filter 20, sorption purification carbon filter 21 and repeated, but already fine purification from mechanical impurities by filter 22. From the output of filter 22 (i.e., from the output of node 17), water through an open valve 24 enters the input of the reverse osmosis membrane 25 either directly (i.e. without using pump 23), or with an additional increase in pressure by this pump. In the membrane 25, water is separated into permeate, which from the outlet 26 of this membrane enters the inlet of the modifying unit 19, and the concentrate, which from the outlet 27 through the controlled hydraulic resistance 28 and through the branch pipe 30 through the corresponding pipeline enters the centralized sewage system. Further, when the permeate passes through the devices 31, 32 and 33 of the modifying unit 19, its (permeate) mineral composition, organoleptic properties, and pH are adjusted according to the parameters of these devices.

Further, the permeate modified in node 19 from the output of this node (i.e., from the output of module 5) through the corresponding pipeline enters the dynamic accumulator 6 until it is completely filled, in which the permeate (drinking water), on the one hand, is temporarily stored until the next sale , and on the other hand, is continuously exposed to ultraviolet irradiation. At the same time, the disinfecting effect of ultraviolet radiation is further enhanced due to the effect of a sudden narrowing of the water flow when it leaves the dynamic accumulator 6 through its outlet pipe due to the flow turbulence caused by this narrowing.

Claims (5)

1. Split system for aqua vending, containing an indoor unit (1) located in an insulated room (2), an outdoor unit (3) located outside the insulated room (2), a supply pipeline (4) hydraulically connecting these blocks and designed for supply of drinking water to the water buyer, as well as means of thermal insulation and electrical heating, while the indoor unit (1) contains a preparation module (5) designed to prepare drinking water from the water of the centralized water supply, a means of storing and supplying drinking water to the container of the water buyer, and the outer block (3) contains a filling chamber (8) designed for pouring water into the container of the water buyer and containing a branch pipe (9) for direct dispensing of water into the container of the water buyer, which is connected to the supply pipeline (4), also the external block (3) contains aqua vending control means and a means of paying for the purchase of drinking water, characterized in that the means of storing drinking water is a dynamic hydraulic accumulator (6) hydraulically connected to the specified preparation module (5) and designed for dynamic accumulation of drinking water with simultaneous ultraviolet sterilization of this dynamically accumulated water , the drinking water supply means is a supply pump (7) designed to supply drinking water to the buyer of water from a dynamic hydraulic accumulator (6) through the supply pipeline (4), and the external unit (3) is made in the form of a wall cabinet in which the listed devices are located , which are part of this block, while this wall cabinet of the block (3) is fixed on the wall (10) of the insulated room (2) on the outside of this wall, in which a hole (11) is made, designed for the supply pipeline to pass through it (4), which passes through this hole (11), so that the outer section of the supply pipeline (4), limited on the one hand by the hole (11), and on the other hand by the specified branch pipe (9), located above the maximum possible water level in the dynamic hydraulic accumulator (6), is equipped with means of thermal insulation and electrical heating of this outer segment, which at the same time has a length less than the length of the entire supply pipeline (4), and the filling chamber (8) in the area of its bottom contains a means (12) for collecting overflowed water, with by which the discharge pipeline (13) is hydraulically connected, designed to drain this overflowing water into the sewer pipe (14) located inside the insulated room (2), while the discharge pipeline (13) passes either through the same hole (11) in the wall (10 ) as the supply pipeline (4), or an additional hole is made in the wall (10) through which the exhaust pipeline (13) passes, so that any hole in the wall (10) through which the exhaust pipeline (13) passes is located below means (12) for collecting overflowed water, while the outer section of the discharge pipeline (13), limited on one side by a hole (11) in the wall (10) or another corresponding hole in the wall (10), through which the discharge pipeline (13) passes, and on the other hand, a means (12) for collecting overflowed water, and this means (12) itself are equipped with means for their thermal insulation and electrical heating. 2. Split system according to claim 1, which contains a valve (15) installed on the supply pipeline (4), while said valve is either a check valve or a solenoid operated valve. 3. Split system according to claim 1, in which the wall cabinet of the outdoor unit (3) is installed at a distance from the zero level (16) of the insulated room (2). 4. Split system according to claim 1, in which the lower part of the supply pipeline (4) is made either in the form of a U-shaped elbow, so that the inlet

-shaped segment of this elbow is hydraulically connected to a dynamic hydraulic accumulator (6) through a branch pipe in the bottom of this hydraulic accumulator, or in the form of a horizontally oriented segment, the input end of which is hydraulically connected to a dynamic hydraulic accumulator (6) through a branch pipe in the lower part of the side wall of this hydraulic accumulator, while the supply pump (7) is made in the form of a submersible centrifugal pump with a "wet" rotor and is located either in the lower part of the specified U-shaped bend of the supply pipeline (4), or in the specified horizontally oriented segment of the supply pipeline (4). 5. Split system according to claim 1, in which the hole (11) is located either within the area of the conditional rectangle specified by the inner and facing the wall (10) perimeter of the wall cabinet of the outdoor unit (3), or between the specified conditional rectangle and the zero level (16) insulated room (2).

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