TR2023009615A2 - APPARATUS USED IN LIQUID COMPOSITIONS CONTAINING ULTRA-FINE BUBBLES AND APPLICATION METHOD OF THIS APPARATUS - Google Patents

Abstract

Meet; Disclosed is a generator that provides an effective and efficient method of producing an activated liquid filled with ultrafine bubbles and methods of using this generator and activated liquid. This generator includes a tubular housing and an elongated component with a specific shape and porous material placed inside. These two parts are configured to form a composition; where both ends of the casing and the internal long permeable component combine to form a water inlet and a water outlet, b) the internal cavity of the long component receives the flowing liquid. c) the space between the outer surface of the elongated component and the inner surface of the housing forms a closed space that can be filled with pressurized gas through a gas inlet. Gas to liquid; can be introduced using a Venturi system or using a pump.

Description

DESCRIPTION APPARATUS USED IN LIQUID COMPOSITIONS CONTAINING ULTRAINE BUBBLES AND APPLICATION METHOD OF THIS APPARATUS TECHNICAL FIELD This invention relates to methods of producing activated ultrafine bubble-filled liquid and methods of using this liquid. This liquid is defined here as an ionized liquid containing a high amount of ultrafine gas bubbles, defined as bubbles less than 1 micron in size. Activated ultra-fine bubble-filled liquid; liquids in polluted seas, lakes and swamps, dams, rivers and the like, or drinking water, industrial water, agricultural water, cooling water and waste oil discharged from factories and gas stations, etc. purification of liquids, cleaning and sterilization of food i.e. agricultural and seafood products, medical treatments, extinguishing unwanted bubbles, preserving the freshness of foods and using hydrogen, carbon dioxide, methane, etc. It can also be used to store gases in liquids. STATE OF THE ART Nanobubbles have many unique properties such as long lifespan in liquid due to their negatively charged surfaces. Nanobubbles also have high gas solubility in liquid due to their high internal pressure. In contrast, micro- and macrobubbles are larger in size and therefore rise rapidly on the water surface. Nanobubbles can be applied in various fields and have numerous beneficial effects in medical, industrial and agricultural terms. For example, the presence of nanobubbles can promote a physiological activity and increase metabolism in living things, resulting in increased ontogenetic growth. To date, various methods have been proposed to produce nanobubbles. These methods include vortex type liquid flow, venturi, high pressure dissolution, ejector, mixed vapor direct contact condensation and supersonic vibration. All these methods are energy-intensive and have varying degrees of success in creating nanobubbles. Liquid production equipment containing ultrafine bubbles less than 10 micrometers in diameter has been used to purify polluted water and is described in Japanese patent application number P 2003-53373A. The equipment is preferably used in polluted seas, lakes and swamps, dams, rivers, etc. It is used to purify liquids. As a result, due to the negativities explained above and the inadequacy of current usage, it has become necessary to make a new approach in the relevant technical field. Therefore, an invention that will overcome these problems is needed. DESCRIPTION OF THE INVENTION The present invention relates to methods of producing activated ultra-fine bubble-filled liquid, methods of using this liquid and the apparatus used in the method in order to eliminate the above-mentioned disadvantages and bring new advantages to the relevant technical field. This liquid is defined here as an ionized liquid containing a high amount of ultrafine gas bubbles, defined as bubbles less than 1 micron in size. Activated ultra-fine bubble-filled liquid; liquids in polluted seas, lakes and swamps, dams, rivers and the like, or drinking water, industrial water, agricultural water, cooling water and waste oil discharged from factories and gas stations, etc. purification of liquids, cleaning and sterilization of food i.e. agricultural and seafood products, medical treatments, extinguishing unwanted bubbles, preserving the freshness of foods and using hydrogen, carbon dioxide, methane, etc. It can also be used to store gases in liquids. In addition to the known properties of water purification, the quenching of ultra-fine gas bubbles (defined as having a diameter of less than 1 micron) present in the activated liquid, such as larger bubbles mixed in particularly viscous liquid, hydrogen, carbon dioxide and methane, etc. Safer and more effective spray for storage, preservation of food, vegetables and meat for longer periods of time, sterilization, medical treatment, fire extinguishing, humidification, fertilization, soil fertilization, expanding the contact area of gas and liquid, reducing surface tension, activating micro gas bubbles. More efficient purification of dirty liquid by taking advantage of effects such as hydroxyl ion and formation of micro clusters caused by the contaminated liquid, etc. It has been experimentally determined by the owner of this invention that it exhibits new features such as. The purpose of this invention is to provide a new method to produce activated liquid containing micro gas bubbles useful for the above mentioned applications. Another aim is to offer new applications for activated liquid. This invention also relates to the technology of reducing or extinguishing harmful bubbles formed in industrial production, environmental treatment, treatment of industrial wastes and similar processes. This invention is also used in sterilization, freshness preservation, humidification, fire suppression, fertilization, improvement of crumbly structure and exchangeable cation of soil, etc. It relates to a method of producing and using activated liquid containing microbubbles of certain gases for certain purposes. DETAILED DESCRIPTION OF THE INVENTION In this detailed explanation, the subject of the invention, the Production Method of Liquid Compositions Containing Ultra-Fine Bubbles and the preferred alternatives of the apparatus used in the method, are explained only for a better understanding of the subject and in a way that does not create any limiting effect. The term "nanobubble" as used herein refers to a bubble with a diameter of less than one micron. A microbubble, larger than a nanobubble, is a bubble with a diameter equal to or greater than one micron and less than 50 microns. A macrobubble is a bubble with a diameter greater than or equal to 50 microns. In one aspect, an apparatus for producing a composition comprising nanobubbles dispersed in a liquid carrier is described. The apparatus includes an elongated housing including a first end and a second end, housing defining a liquid inlet, a liquid outlet, and an internal cavity adapted to receive liquid carrier from a liquid source, and a gas permeable member at least partially disposed within the internal cavity of the housing. The gas permeable member includes an open end adapted to receive a pressurized gas from a gas source, a closed end, and a porous side wall extending between the open and closed ends and having an average pore size of not greater than 1.0 micrometers. The gas permeable element defines an inner surface, an outer surface and a lumen. The liquid inlet of the housing is arranged to introduce the liquid carrier from the liquid source into the interior space of the housing at an angle that is generally orthogonal (perpendicular) to the outer surface of the gas-permeable member. The casing and gas permeable element, while the liquid coming from the liquid source flows parallel to the outer surface of the gas permeable element from the carrier liquid inlet to the liquid outlet, the pressurized gas given to the lumen of the gas permeable element creates nanobubbles through the porous side wall of the gas permeable element and over the outer surface of the gas permeable element. It is configured to form a composition containing the liquid carrier and nanobubbles dispersed in it by being forced to pass in the form of a liquid. In some embodiments, the composition is essentially free of microbubbles when measured 10 minutes after exiting the liquid outlet. A composition that is "essentially microbubble-free" means that the microbubbles are less than the total bubble volume in the composition. The average diameter of the nanobubbles may be less than 500 nm or less than 200 nm, or may range from about 10 nm to about 500 nm (e.g., about 75 nm). to about 200 nm). The concentration of nanobubbles in the liquid carrier at the liquid outlet can be at least 1X101 nanobubbles/ml. In some embodiments, the composition includes nanobubbles within the liquid carrier that are stable for at least one month or at least three months under ambient pressure and temperature. Gas; can be selected from the group consisting of air, oxygen, carbon dioxide, nitrogen, hydrogen and combinations thereof. In some embodiments, the gas permeable element may be adapted to receive gas pressurized to at least 5 psi or up to at least 100 psi. The liquid carrier may contain water. In some applications, the liquid carrier does not contain surfactants. The porous sidewall may have an average pore size ranging from 0.45 micrometer to 1 micrometer. The porous sidewall may include a porous coating. Examples of suitable porous coatings include metallic oxides such as alumina, titania, zirconia, manganese and combinations thereof. The porous coating can be applied to the inner surface, outer surface, or both of the gas-permeable element. In some applications, the enclosure contains a plurality of gas-permeable elements. The gas-permeable element may be in the form of a single-channel tube or a multi-channel tube. The apparatus includes a helical element (or helical apparatus) adapted to increase turbulence in the liquid carrier. An apparatus for producing a composition comprising nanobubbles dispersed in a liquid carrier is described. The apparatus includes an elongated housing including a first end and a second end, the housing defining a liquid inlet, a liquid outlet, and an internal cavity adapted to receive liquid carrier from a liquid source, and a gas permeable tube disposed within the internal cavity of the housing. The gas permeable tube includes an open end, a closed end, an inner surface, an outer surface, and a lumen adapted to receive a pressurized gas from a gas source. The liquid inlet of the chamber is designed so that the gas-carrying liquid enters the tube space from the liquid source, usually at an angle where the inner surface of the tube rotates with the pressure applied from the outlet of the tube based on vortex-shaped channels. The gas dissolves and comes out. Gas in the form of nanobubbles on the inner surface of the tube flows from the liquid source into a vortex state, and this rotation creates a combination of the liquid carrier and the nanobubbles inside. A method is described for producing a composition comprising nanobubbles dispersed in a liquid carrier using the apparatus described above. The method involves introducing a liquid carrier from a liquid source into the internal cavity of the housing through the liquid inlet of the housing at a flow rate that produces turbulent flow on the outer surface of the gas-permeable element. The method further includes introducing a pressurized gas from a gas source into the gas-permeable element at a gas pressure selected such that the pressure outside the internal cavity of the enclosure is greater than the pressure inside, thereby forcing the gas to pass through the porous side wall and forming nanobubbles on the outer surface of the gas-permeable element. The liquid carrier flows parallel to the outer surface of the gas-permeable element from the liquid inlet to the liquid outlet and removes nanobubbles from the outer surface of the gas-permeable element to form a composition containing the liquid carrier and nanobubbles dispersed in it. The compositions described above, in which nanobubbles are dispersed in a liquid carrier, are useful in a number of applications. For example, the compositions can be used to purify water by transporting the composition to water in need of purification. Examples of water resources that can be treated include wastewater, oxygen-deficient water, drinking water and aquaculture water. In another embodiment, the compositions described above may be combined with a liquid to form a pumpable composition having a viscosity lower than the viscosity of the liquid, and the pumpable composition may then be transported to a desired target via a pipe. Examples of liquids are crude oil and drilling fluids. In another embodiment, the composition described above may be combined with a liquid to form an oxygen-enriched composition and then applied to plant roots to enhance plant growth. In an exemplary method, it is produced by introducing gas under pressure and the structure has a pore size between 0.45-1 micrometer. Thus, the gas passes through the ceramic structure and emerges as nanobubbles on the other side, and as it emerges from said structure, it creates a liquid flow on that other side of the ceramic structure to carry the nanobubbles, thus preventing the nanobubbles from coalescing to form larger sized bubbles. An exemplary apparatus for producing nanobubbles includes a porous structure having a first surface and an opposing second surface, a gas supply system for supplying gas under pressure to said first surface of the structure such that the gas passes through said structure and exits through said second surface, and said The second includes a fluid supply system for supplying fluid under pressure as a stream flowing over the surface. The device may further include an elongated housing coaxial with said orifice having an inlet for the liquid at one end and an outlet for the liquid at the other end so that the liquid flows through the cylindrical channel defined between the orifice and the housing. The inlet to the casing may be positioned so that the liquid flows into the casing at an angle relative to the direction of flow through the casing. Protrusions such as helical elements may be provided in said enclosure to increase turbulent flow in the duct. Apparatus and method for creating nanobubbles with a bubble diameter of not more than 100 nm in a solution, using minimum energy, in which the nanobubbles remain dispersed in the liquid carrier for one or more months in a stable state under ambient temperature and pressure. It makes it possible to form bubbles. High concentrations of nanobubbles can be produced in a liquid carrier. Moreover, depending on the nature of the gas inside the nanobubbles, the solution containing the nanobubbles may have a physiological activation and/or growth-promoting effect on animals, plants, organisms and/or microorganisms; a lethal or anti-proliferative effect on microorganisms such as bacteria and viruses; It can cause a chemical reaction with an organic or inorganic substance or the mixing of a gas with a liquid. In addition, a major advantage of a composition containing gas carried within nanobubbles is that nanobubbles increase a saturation point in a liquid. The nanobubbles in the composition increase the maximum saturation point of the liquid. Details of one or more embodiments of the invention are set forth in the description below. Other features, objects and advantages of the invention will be clearly understood from the description and claims. The term ultrafine bubble refers to bubbles with a diameter of less than 1 micron (according to ISO standard 20480-1). Activated UFB-filled fluid is defined as fluid containing a sufficient amount of ultrafine bubbles. This activated UFB-filled LVL exhibits very useful properties and can be used for a variety of applications, including novel applications that will be described below. This invention provides the methods described below. The activated liquid containing microbubbles is hereinafter referred to as SLVl. Method for Producing SLV: When water and gas liquid pass through the opposite s poles and are mixed with the help of a vortex, and then when the liquid meets the s and n poles, the amount of bubbles increases by at least 70% and the amount of bubbles also increases during exit from the pipe. A slightly larger bubble will be formed. Bubble Deflation Method This invention is based on the newly found properties of LVL and is widely used in industrial production, environmental treatment, industrial waste treatment, etc. It relates to a method to extinguish harmful bubbles formed in processes. Specific LVl It becomes possible to produce specific LVl types that were not possible to produce with previous methods. In some embodiments, the gas pressure within tube 20 is pressurized to at least 5 psi or up to 100 psi. Higher pressures can also be used. Any of the compositions described herein produced by the apparatus contain nanobubbles with an average diameter of less than 1 micron. In some embodiments, the nanobubbles have a mean diameter ranging from about 10 nm to about 200 nm, from about 50 nm to about 300 nm, or from about 10 nm to about 150 nm. The nanobubbles in the composition may have a unimodal diameter distribution where the average bubble diameter is less than 1 micron. The compositions provided herein contain a high concentration of nanobubbles dispersed in the liquid carrier. In some embodiments, the composition includes a concentration of nanobubbles in the liquid carrier at the liquid outlet of at least 1X101 nanobubbles/ml. The apparatus and method provided herein can produce compositions in which the liquid carrier includes nanobubbles that remain stationary for a desired period of time. In some embodiments, the composition provided herein includes nanobubbles in the liquid carrier that are stable under ambient pressure and temperature for at least one month, and preferably at least 3 months. The nanobubble-containing compositions described above are useful in a number of applications. Because nanobubbles are stable in the liquid carrier, they can be transported over long distances without dissolving or coalescing in the liquid carrier. Additionally, since the concentration of nanobubbles in the liquid composition is high, nanobubbles are an effective source for transporting gas to a desired source. In addition, compositions containing nanobubbles with smaller surface area and higher solubility are much more effective than traditional aeration in transferring gases such as oxygen to the liquid. One application involves a water purification process in which a composition containing nanobubbles dispersed in a liquid carrier is transported to a water source in need of purification. Examples of water that can be treated include wastewater, oxygen-deficient water, drinking water and aquaculture water. In the case of drinking water, nanobubbles can be used to create drinkable water. Nanobubbles can also be used in carbonated drinking water. A particularly beneficial water purification practice involves environmental water reclamation. Because nanobubbles have a long lifetime in water and significant mixing potential, the compositions can be used to improve the ecological balance of lakes, rivers and the ocean. Enriching water bodies with abundant oxygen can help restore beneficial aerobic activity, which works to break down sludge, hydrogen sulfide, environmental toxins, and pathogenic organisms. Another application is the transportation of liquids such as crude oil or drilling fluids through pipes. Often these liquids are viscous and must be transported over significant distances. The composition containing nanobubbles dispersed in a liquid carrier can be combined with the liquid to form a pumpable composition with a viscosity lower than that of the liquid to form a pumpable composition that can be transported through a pipe to a desired target. Another application involves processing plant roots to promote plant growth. For example, a composition containing nanobubbles dispersed in a liquid carrier can be combined with another liquid to create an oxygen-enriched composition, which is then applied to plant roots. Similarly, compositions containing nanobubbles in a liquid carrier can be used in aquaculture to create a hyperoxic environment that supports the growth of fish and crustaceans. Another application involves improving heat transfer. For example, heating or cooling liquids injected with compositions containing nanobubbles in a liquid carrier can create faster temperature changes in these liquids. A non-limiting exemplary embodiment includes a cooling tower application. Another application is to use compositions containing nanobubbles in a liquid carrier for sterilization. As the nanobubbles collapse, oxygen becomes active in the air and forms molecules such as O and OH-. These molecules are powerful sterilizers that can be used to destroy pathogenic organisms and certain volatile organic compounds. Another application involves tissue preservation. Combining the nanobubble composition with tissue cells can preserve the cells even after freezing. Another application includes evaporation. Compositions containing nanobubbles dispersed in a liquid carrier have a higher evaporation potential than regular water. Therefore, combining water in cooling towers with nanobubble compositions can enhance the evaporation of cooling tower waters and increase the efficiency of associated cooling processes. Another application involves using nanobubble compositions to purify membranes or geothermal wells. When membranes or geothermal wells are continuously exposed to compositions containing nanobubbles in a liquid carrier, the compositions can prevent contaminant accumulation on the membrane or geothermal well surface. This is because nanobubbles are negatively charged and can form geometric structures (e.g., cages) on the membrane or geothermal well surface that exclude certain contaminants. A number of embodiments of the invention have been described. However, it will be understood that various modifications can be made without departing from the spirit and scope of the invention. Accordingly, other embodiments are also within the scope of the claims set forth below. Especially when the liquid is water, oxygen molecules are taken into the water due to hydration, and the adsorption of positively ionized air to the oxygen atoms of water molecules and also the adsorption of negatively ionized air molecules to the hydrogen atoms of water molecules is accelerated. Thus, the ring-shaped activator can accelerate and double the activation effect occurring in the space formed between the fixed tube and the inner vortex.TR TR TR