RU2778684C2 - System for purification and regulation of the physico-chemical composition of water and the use of the resulting water - Google Patents

Abstract

FIELD: water purification.

SUBSTANCE: invention relates to the field of purification, regulation of the physico-chemical composition and packaging of alkaline, ionized, ozonated, isotonic, featuring antioxidant and detox activity, magnesium-enriched drinking water in an unparalleled, environmentally friendly container by means of modular, portable and inexpensive installations. A system is proposed containing a pump (1), which takes water from groundwater or another water source and stores it in a tank (2), from which, using a high-pressure pump (3), water is directed through a heat exchanger (4) with alternating plates, heating it to a temperature of 60°C, and is brought to a high-pressure sand filter (5), followed by a high-pressure filter (6) with activated carbon and an ion exchange filter (7), followed by means of adding strong bases (8) to regulate the concentration of hydrogen ions; in this case, the specified water is sent to a fine filter (9) and then to a two-pass reverse osmosis unit (10), after which the water being passed is evaluated by a hydrogen ion concentration sensor (11), which is connected to a means of adding a strong base (8) to regulate the concentration of hydrogen ions to a pH value from 7 to 12, and then stored in a storage tank (12); and by means of a second high-pressure pump (13), they are set in motion using the specified system that receives ozone from the ozonation system (14), and then mineral salts are added to the passing water through mineral salt addition means (15) with 94 mineral salts, and magnesium salts are introduced into the water in an amount from 20 to 60 mg/l with the help of means for adding magnesium salts (16), after which the specified water is stored in a storage tank (17) and then successively fed to a complex of devices for packing (18) in bags (30), consisting of a mixture of low-density polyethylene (LDPE) and LDPE with a linear structure of monomers designed for single filling, including cold welding seams (31), while the contour of these seams mainly imitates the shape of a bottle with a neck (34), and a line (36) to indicate the best way for the user to open the bag (30), which has printed elements (35), including useful information for users. It is also proposed to use this system for the preparation of hospital beverages, soft drinks, jellies, juices, tea, flavored water and other solutions, mixtures and colloids in which water is used as a solvent or carrier.

EFFECT: proposed invention makes it possible to obtain an industrial system for cleaning, regulating the physico-chemical composition and packaging of drinking water, having a reduced scale.

7 cl, 4 dwg

Description

Technical field

[0001] The design principles and functionality of the present invention relate to the purification, physico-chemical composition control and packaging of alkalized, ionized, ozonized, isotonic, antioxidant and detoxic, magnesium-enriched drinking water in an unparalleled, environmentally friendly container through modular , portable and inexpensive installations.

State of the art

[0002] There are several systems on the market for purifying and converting water from various sources for human consumption.

[0003] Water with a hydrogen ion concentration (quantified by pH value) in the range of 7 to 12 (preferably 8.5 to 10.5) is suitable for human consumption, as well as a wide range of mineral salts, mainly magnesium, in the range of 20 to 60 mg per liter of water, preferably above 40 mg per liter.

[0004] In the prior art, some patent documents related to water purification methods are known, such as Chinese document CN 205856183U, which describes a method for purifying cold water without further use for human consumption. Another example is patent document CN 103880213, which also describes a cold water purification process involving very large plants, but does not solve the problem of providing suitable packaging that facilitates competitive access to the consumer. With respect to packaging, the present inventors have found US 8303182B2, a North American document describing dual-seal polymer blend packaging with a high amount of solid waste per unit volume of liquid.

[0005] Prior art solutions include equipment and methods implemented in large-scale installations that require large investments in land and infrastructure, as well as high fixed costs. Therefore, there is a need for an industrial system for purification, chemical composition control and packaging of drinking water, having a reduced scale, which would allow for a variety of installation options, operate in a small area with less infrastructure requirements, and achieve greater convenience for the end user.

[0006] With the current state of the art, there is still a need for more healthy drinking water packaged in an environmentally friendly sealed container, recyclable and with less solid waste per ml of water, more energy efficient and with lower CO2 emissions. ₂ in production, freezing and transport, which is obtained through a system installed and operated in a small area, with minimal infrastructure requirements.

Disclosure of the essence of the invention

[0007] The present invention relates to a system for purifying, controlling the physico-chemical composition and packaging of drinking water, containing the following components:

[0008] A pump (1) that draws water from groundwater or another source of water and stores it in a reservoir (2), a high pressure pump (3), an interleaved plate heat exchanger (4); high pressure sand filter (5); high pressure activated carbon filter (6); ion exchange filter (7); means for regulating the concentration of hydrogen ions (8) (not shown in the figure); fine filter (9); two-pass reverse osmosis unit (10); a hydrogen ion concentration sensor (11) connected to means for controlling the hydrogen ion concentration (8); storage tank (12); second high pressure pump (13); ozonation system (14); means for adding mineral salts (15); agents for adding magnesium salts (16); storage tank (17); and a set of devices for filling single packages (18) in the form of bags (30) consisting of a mixture of LDPE and LDPE with a linear structure of monomers intended for single filling, including cold welding seams (31), while the contour of these seams mainly imitates the shape bottles with a neck (34), and a line (36) to indicate the best way for the user to open the package (30), which has printed elements (35) on the outside, including useful information for users.

Objects of the present invention

[0009] The object of the present invention is to provide health protection, environmental protection and social development through the consumption of water by people. Said alkalized water is obtained from any water source such as rain, sea, river, lake or groundwater with minimal energy consumption, reduced CO2 _emissions , reduced plastic residue in a compact system that purifies, alkalizes, salts and ozonates bottled water , with significantly lower investment, infrastructure and operating costs, ensuring its serial compact installation around the globe.

[00010] Another object of the present invention is to provide higher and unparalleled quality water for human consumption that is packaged in an environmentally friendly, more thermally efficient, tamper-evident, recyclable container with the lowest weight and volume of solid waste per ml packaged amount _of water that is easy to transport and process with less CO2 emissions and fuel consumption, obtained through a compact packaging system with minimal infrastructure requirements, allowing serial installation of these systems around the world.

Brief description of the drawings

- In FIG. 1 is a block diagram of the main steps of the methods included in the system according to the present invention.

- In FIG. 2 shows a series system constructed in accordance with the principles of the present invention.

- In FIG. 3 is a plan view of the system shown in FIG. 2 showing the spatial layout of the equipment of the system according to the present invention.

- In FIG. 4 shows the filling process (3) in accordance with the principles of the present invention.

Detailed description of the invention

[00011] First of all, it is necessary to connect the system to a water source at a room temperature of about 25°C, which can come from soil, rivers, lakes, seas, rains and other sources by operating the pump (1) at a pressure of 0.1 to 0.3 atm, preferably 0.2 atm, with water being transferred to a stainless steel tank (2).

[00012] When pumping from said tank (2) by means of a high pressure pump (3) operating at a pressure of 1 to 2 atm, preferably 1.5 atm, the water reaches a pressure of 1.5 atm and passes through the alternating plates of the heat exchanger (4 ) in which the water is initially heated to a temperature of 50 to 70°C, preferably 60°C. According to literature data, under these conditions, water has a dynamic viscosity of 0.4668 mPa/s and a surface tension of about 6.6×10 ^-2 N/m. These changes in the physical and chemical properties of water lead to greater efficiency of subsequent filtration processes. The high pressure heated water is then directed to a high pressure sand filter (5) which serves to remove suspended solids ranging in size from 20 to 100 microns. The water is then passed through a high pressure activated carbon filter (6) and an ion exchange filter (7).

[00013] Upon exiting the ion exchange filter (7), the concentration of hydrogen ions is adjusted by alkalizing the water by adding certain volumes of strong bases such as, for example, NaOH or KOH. Said means for introducing additives are not shown in FIG. 2 and are two small tanks, each containing aqueous solutions of NaOH and KOH, and pumps for feeding them into a fresh filtered water stream. The NaOH solution in the tank should have a concentration in the range of 8 to 12%, preferably 10%, and the KOH solution should have a concentration in the range of 8 to 12%, preferably 10%. This addition of certain volumes of NaOH and/or KOH occurs in accordance with the readings of the sensor for the concentration of hydrogen ions in water (11), located at the outlet of the reverse osmosis unit.

[00014] Then, after adding certain volumes of NaOH and KOH using a high pressure pump with an operating range of 8 to 10 atm, preferably 9.5 atm, not shown in FIG. 2, the water is sent to a fine filter (9) necessary to remove excess K ⁺ and Na ⁺ cations added to the water. At this stage, the water temperature is already around 40°C, since the passage through the successive filters results in heat loss.

[00015] The water then passes through a two pass reverse osmosis unit (10).

[00016] After that, as noted above, the concentration of hydrogen ions is measured using a sensor (11) located in the water flow and connected to the means for adding a strong base, such as NaOH and KOH (8), and the corresponding volume of the specified base is added until the desired pH is reached. Subsequently, the water is stored in an intermediate tank (12).

[00017] When pumping out of the tank (12) using a pump (13) operating in the range from 0.1 to 0.3 atm, preferably 0.2 atm, water is passed through the pipes of the system and enriched with ozone from the ozone generator (14) .

[00018] The mineral salts and magnesium salts are then added to the water stream by means of adding mineral salts (15) and magnesium salts (16). Such means for adding salt include 2 small reservoirs each containing a solution of mineral and magnesium salts and small infusion pumps, not shown in the figure, to add the desired amount of mineral and magnesium salts. The concentration of the mineral salt solution may vary from 20 to 40 mg/l, preferably 30 mg/l, and the concentration of the magnesium salt solution may vary from 20 to 60 mg/l, preferably 40 mg/l.

[00019] After that, the water is stored in the final tank (17) and then served in a set of apparatus for filling single packages (18).

[00020] An example of the system of the present invention is represented by a serial line in figure 2. Such equipment is spatially located on an area of 240 m ² with a height of 2 m with a volume of 480 m ³ required for installation of equipment, as shown in figure 3. Alternatively, the system can work from a source of pressurized water.

[00021] The interleaved plate heat exchanger (4) serves to increase the temperature from 40 to 80°C, preferably from 55 to 65°C, and hence to reduce density, surface tension and viscosity to facilitate the subsequent filtration step.

[00022] After passing through the first interleaved plate heat exchanger (11), water at a temperature of 40 to 60°C enters a sand filter (12), which serves to remove suspended solids ranging in size from 20 to 100 microns. The flow of water through this element is facilitated by the reduction in density, surface tension and viscosity, which are provided by previous heating.

[00023] After passing through the sand filter (12), the water enters the activated carbon filter (13), this time at a deliberately lower temperature, preferably in the range of 30 to 60°C, preferably in the range of 35 to 45°C , due to heat loss when passing through the sand filter. The purpose of the activated carbon filter (13) is to remove chlorine, algae, colored substances, aromatic compounds and other substances that can give the water a strange taste.

[00024] Next, the water enters the ion exchange filter (14). At this stage, the water flows in close contact with large surface cation and anion resin resin beads designed to remove unwanted metal ions, mainly heavy metals, by chemical affinity.

[00025] After passing the ion exchange filter (14), certain volumes of aqueous solutions of strong bases, such as, for example, NaOH or KOH, are added to the water stream to adjust the concentration of hydrogen ions in accordance with the readings of the sensor (11) by means of adding (8), not shown in the figure. Such addition means are two small tanks, each containing aqueous solutions of NaOH and KOH, and pumps for adding volumes of such solutions to fresh filtered water. The NaOH solution in the tank should have a concentration in the range of 8 to 12%, preferably 10%, and the KOH solution should have a concentration in the range of 8 to 12%, preferably 10%.

[00026] The water stream then enters a fine filter (9) designed to retain the K ⁺ and Na ⁺ cations added while adjusting the pH value.

[00027] After the ion exchange filter, the water is sent to a double reverse osmosis unit (16), the function of which is to separate, through ultra-thin membranes, permeate (pure water) from waste products consisting of salts, organic substances and any contaminants in suspension with a size greater than 5 microns, in addition to 99.9% of bacteria possibly present.

[00028] In the next step of the process, the water passes through an ozonizer (14) in which the resulting ozone in gaseous state (O ₃ ) is bubbled abundantly through the water stream, guaranteeing 100% mortality of any type of living cells (algae, bacteria, yeast, fungi, etc.). .d.) and oxidation of any traces of organic material. This process step guarantees the purity, clarification, freshness and shelf life of bottled water for 2 years.

[00029] An example of the system of the present invention is shown in figure 3, in which the equipment is placed on an area of 240 m ² and a height of 2 m, resulting in an installation volume of 480 m ³ . The system built in accordance with the system in Figure 3 is capable of cleaning and filling 5,000 liters per hour. In other words, the performance of the system built in accordance with figure 3, approximately 10 l/m ³ installation for 1 hour.

[00030] The system of the present invention guarantees 100% mortality of any type of cellular life such as heterotrophic bacteria, common coliform bacteria, Echerichia coli (algae, bacteria, yeast, fungi, etc.) and oxidation of any traces of organic material in the passing stream water. This method guarantees the purity, clarification, freshness and shelf life of bottled water for 2 years.

[00031] Thus, according to the method of the present invention, absolutely pure water is obtained, the composition of which is still properly balanced to achieve breakthrough and unprecedented health standards for human consumption. In this case, for human consumption is understood not only the simple consumption of water, but also the preparation of drinks with water, alkaline and with a high concentration of magnesium salts, especially hospital drinks, soft drinks, jellies, juices, teas, flavored water and other solutions, mixtures and colloids in which water is used as a solvent or carrier.

[00032] At the moment, pH is monitored and regulated (8) by measuring the pH value using a sensor (11) and a metering pump (8) (not shown in the figure), which serves to balanced and automatically add sodium bicarbonate, which, due to chemical affinity leaves sodium ions in water in the form of sodium hydroxide, which leads to the regulation of the concentration of hydrogen ions (H ⁺ ). The adjustment is carried out so that the final product has an alkaline pH of 7.0 to 12.0, preferably 8.5 to 10.5.

[00033] The water is then passed through the salt addition means (15 and 16). At this stage, a premix containing Himalayan pink salt and magnesium salts is added to the water to introduce up to 94 kinds of mineral salts (15) with high hydrating and regenerating ability, among which magnesium salts are distinguished. It should be noted that Himalayan pink salt itself already contains magnesium salts, which are the third most concentrated main component. This metal is present in significant amounts in Himalayan soil containing ores such as magnesite (MgCO ₃ ), dolomite (CaMg(CO ₃ ) ₂ ) and brucite (Mg(OH) ₂ ), compounds with a magnesium content of 46.6%, 22 % and 69%, respectively, which are used for the commercial extraction of said element (according to a 2009 report by the Ministry of Petroleum and Natural Resources of Pakistan). Despite the presence of magnesium in Himalayan salt, the premix may contain other sources of magnesium (16) in order to increase or regulate its concentration, for example, by adding magnesium chloride. As can be seen from FIG. 2, in the present example, separate salt addition agents (15) and magnesium salt addition agents (16) were selected by the present inventors. That is, the means for adding salts can be separated to provide a separate means for adding magnesium salts.

[00034] It should be noted here that there is a difference between salt addition agents (15 and 16) and pH control agents (8 and 11), the latter, despite measuring the concentration of salts such as sodium hydroxide, are intended to regulate the pH value of the water, as explained earlier. This is due to the fact that in the human body, the normal blood pH level must be maintained within a narrow range (7.35 to 7.45) for the proper functioning of metabolic processes and to deliver the right amount of oxygen to the tissues. Metabolism produces large amounts of acids that must be neutralized or eliminated to maintain acid-base balance. The lungs and kidneys are the main organs involved in the regulation of blood pH, while blood buffer systems (hemoglobin, plasma proteins, bicarbonates and phosphates) also contribute to the regulation of pH up to 7. It is worth emphasizing that the pH value of food and drink is not necessarily associated with acidifying effect in the body.

[0035] The alkalizing or acidifying capacity of a food is determined by the content of sulfates, chlorides, phosphorus, potassium, magnesium, sodium and calcium, and it can be calculated from PRAL (potential acid load on the kidneys , in Portuguese, carga ácida renal potencial ). PRAL is a mathematical calculation created by Thomas Römer and Friedrich Manz in 1995 that allows for the direct evaluation of the aforementioned components in foods. The more negative the PRAL value, the more alkalizing the food is. Consumption of alkalizing foods and drinks (i.e. those with a negative PRAL value) has a pronounced effect on the acid-base balance in the body. In the case of water, it is known that the higher the magnesium and/or bicarbonate concentration, the lower the PRAL value. In this sense, the consumption of drinking alkalizing water has gained prominence. Several studies have noted the beneficial potential of alkalinizing diets, emphasizing the preservation of muscle mass in older adults and the support of bone health. In the present system, the salt addition means (18) will control the PRAL value of the water resulting from said process in the range of -1 to -3.

[00036] The calculation of the PRAL value can be performed using the following formula, suitable for mineral waters: PRAL = [0.00049 SO ₄ (mg)] + [0.027 Cl (mg)] + [0.037 P (mg)] - [0, 21 K(mg)] - [0.026 Mg(mg)] - [0.413 Na(mg)] - [0.013 Ca(mg)] (source: Revista Nutrire. 2015 Dec; 40(3): 344-351, available at the following email address: http://dx.doi.org/10.4322/2316-7874.78015).

[00037] At the end of this step, we have obtained pure water suitable for human consumption with a PRAL value in the range of -1 to -3 and a hydrogen ion concentration in the range of 7.0 to 12, preferably 8.5 to 10 ,5, with a unique availability of 94 mineral salts, especially a magnesium content of 20 to 60 mg per liter of water, preferably above 40 mg per liter. This water has a greater hydrating capacity than ordinary mineral water. Due to its low surface tension and differentiated molecular structure, it contains more oxygen, has antioxidant properties, is ionized and ozonized. Water is stored in a tank (17).

[00038] The system also includes a set of apparatuses for filling unit packages (18) for the purpose of packaging the water obtained as a result of the implementation of this method, for subsequent distribution near its production. In this case, a suitable packaging solution would be in tamper-evident packages of a mixture of LDPE and LDPE with a linear monomeric structure produced by a cold rolling process.

[00039] In accordance with the example shown in FIG. 2, the system comprises a thermal seal volumetric injection packaging unit (18) capable of packaging between 4,000 and 8,000 packets of water (30) per hour, as shown in FIG. 3, the typical volume of this type of packaging can vary from 150 ml to 1500 ml.

[00040] It should be noted that the package (30) shown in FIG. 4 consists of LDPE films with linear monomeric LDPE joined by welds (31), the contour of the welds predominantly imitating the shape of a traditional bottle with a neck (34). The user can cut or tear the neck (34) to access the contents through the hole in the neck (34) and drink the packaged water.

[00041] The process of opening the neck (34) is irreversible, which confirms the possibility of reusing the package (30).

[00042] The package (30) itself contains printed information. The printed elements (35) are preformed and externally on the bag itself, since preferably the packaging unit (18) will be provided with prefabricated bags made of low density polyethylene (LDPE) films.

[00043] Even more preferably, the printed elements (35) include useful information for users, such as, for example, the volume of the package, legal information, the outline of a water bottle, or an article that may be more convenient.

[00044] A line (36) may be indicated on the package indicating to the user the best part of the neck (34) to open the package (30). Said opening in the neck (34) will allow the user to insert a straw or allow water to escape by applying pressure to the sides of the bag in order to consume the packaged water.

[00045] The description of the example provided herein does not exclude other possible embodiments and tools that are within the scope of the present invention, and therefore should not be construed as limiting. In this sense, a person skilled in the art can use several sets of sensors and controllers, tanks and pumps to control a system designed in accordance with the principles of the present invention.

Claims (7)

1. A system for cleaning and adjusting the physico-chemical composition of drinking water, containing a pump (1), which takes water from groundwater or another source of water and stores it in a tank (2), from which water is directed using a high-pressure pump (3) through a heat exchanger (4) with alternating plates, heating it to a temperature of 60°C, and lead to a high pressure sand filter (5), followed by a high pressure filter (6) with activated carbon and an ion exchange filter (7), after which are located means for adding strong bases (8) for adjusting the concentration of hydrogen ions; at the same time, said water is sent to a fine filter (9) and then to a two-pass reverse osmosis unit (10), after which the passed water is estimated by a hydrogen ion concentration sensor (11), which is connected to a means for adding a strong base (8) to control the ion concentration hydrogen to a pH value of 7 to 12, and then stored in a storage tank (12); and by means of the second high pressure pump (13) is driven by said system receiving ozone from the ozonation system (14), and then mineral salts are added to the passing water by means of mineral salt addition means (15) with 94 mineral salts, and in water is injected with magnesium salts in an amount of 20 to 60 mg/l using means for adding magnesium salts (16), after which the specified water is stored in a storage tank (17) and then sequentially fed into a complex of devices for packaging (18) in bags (30), consisting of a mixture of low density polyethylene (LDPE) and LDPE with a linear structure of monomers, intended for single filling, including cold welding seams (31), while the contour of these seams mainly imitates the shape of a bottle with a neck (34), and a line (36) indicating to the user the best part of the neck (34) to open the package (30) which has printed elements (35) including useful information for users. 2. The system according to claim 1, in which the specified system is designed to produce water with a pH in the pH range from 8.5 to 10.5 with a high oxygen content, antioxidant and antitoxic effects. 3. A system according to claim 1 or 2, wherein said system is designed to produce isotonic, ionized, and ozonized water with a Potential Kidney Acid Load (PRAL) value of -1 to -3. 4. The system according to paragraphs. 1, 2 or 3, in which said system occupies a certain volume of 480 m ³ . 5. The system according to paragraphs. 1, 2, 3 or 4, in which said system is designed to produce 10 liters of mineralized water per 1 m ^{3 of} installed equipment per hour. 6. The system according to paragraphs. 1, 2, 3, 4 or 5, in which the strong base (8) is NaOH or KOH. 7. Application of the system according to paragraphs. 1, 2, 3, 4, 5, and 6 for the preparation of hospital drinks, soft drinks, jellies, juices, teas, flavored waters, and other solutions, mixtures, and colloids in which water is used as the solvent or carrier.

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