Patent Publication Number: US-2022212922-A1

Title: Method for Manufacturing Hydrogen Microbubbles and Device Thereof

Description:
TECHNICAL FIELD 
     The present application relates to a technical field of hydrogen microbubbles and, more particularly, to a method for manufacturing hydrogen microbubbles and the device thereof. 
     BACKGROUND TECHNOLOGY 
     Nowadays, it is known that microbubbles are added in the water and available for agriculture, irrigation, fishery, farming, food processing, and industrial cleanup, the diameter of the microbubbles in the water is usually about 50 micrometer, to form a visual effect of emulsification in the water, and the microbubbles can stay in the water during a longer time. Afterwards, application of the microbubbles, initially increases the dissolved oxygen content in the aquarium required for farming of ornamental fishes, then gradually applies the technology to agriculture, irrigation, fishery, farming, food processing, and industrial cleanup, the method utilizes air bottles of high cost to individually cast a gas, such as hydrogen, oxygen, nitrogen, carbon dioxide, and ozone, using the unique property of various gases, to execute different kinds of work according to the targets, but, in application of the microbubbles, except the oxygen, the hydrogen microbubbles are particularly outstanding in use, the feature of the hydrogen microbubbles is in that, the hydrogen in the microbubbles produces a micro-range high temperature blast during the instantaneous cracking process, various organic mixtures in the water, including microbes, virus, bacteria or pollutants, are burned, cleared, and diminished by the micro-range high temperature blast, thereby achieving the purpose of purifying the water quality physically. 
     Further, in order to prevent use of individual hydrogen air bottles with high cost, the market is turned to use an electrolyzer for applying the hydrogen microbubbles in the water, in application of the electrolyzer, it uses an electric power for discharging to decompose water molecules contained in the air into hydrogen and oxygen, the hydrogen and oxygen are pressurized to enter the water to form microbubbles, wherein the hydrogen microbubbles are soaked in the water to cause a micro-range high temperature blast. 
     However, it is necessary to provide a large amount of electric power to the conventional electrolyzer, so as to be able to decompose the water molecules into hydrogen and oxygen, and the electrolyzer has to stop operating for maintenance and replacement so as to keep the normal operating efficiency, so that the cost of the electrolyzer is very high, and the electrolyzer cannot attract the consumers, thereby affecting the popularity and acceptance of the electrolyzer. 
     CONTENT OF THE INVENTION 
     The objective of the present application is to provide a method for manufacturing hydrogen microbubbles and the device thereof, using hydrogen oscillators made of a magnesium alloy to apply a chemical reaction to the water molecules contained in the gas to form hydrogen, thereby reducing the cost for making the hydrogen. 
     A method for manufacturing hydrogen microbubbles of the present application, at least comprises an air pressurizing assembly, and at least comprises a water container, the manufacturing method comprises the steps: 
     step a, the water container contains water; 
     step b, the air pressurizing assembly sucks and pressurizes a gas to enter at least a hydrogen oscillation generating unit, the hydrogen oscillation generating unit has an interior distributed with hydrogen oscillators made of a magnesium alloy, the hydrogen oscillators chemically reacts with water molecules contained in the gas to form magnesium oxide and hydrogen; 
     step c, the hydrogen oscillation generating unit drives the gas after the chemical reaction to pass a gas nozzle head which injects the gas into the water, and the gas nozzle head is at least provided with a micro-gas spray orifice, the gas after oscillation passes the micro-gas spray orifice and is injected into the water to form hydrogen microbubbles which contains hydrogen. 
     A hydrogen microbubbles device of the present application at least comprises an air pressurizing assembly, the air pressurizing assembly at least includes an air inlet terminal and an air outlet terminal, one side of the air inlet terminal is at least connected with an air inlet unit, the air inlet unit is at least provided with an air inlet hole penetrating the air inlet terminal, then, the air outlet terminal is at least connected with a hydrogen oscillation generating unit, the hydrogen oscillation generating unit has an interior provided with a receiving chamber connected to the air outlet terminal, the receiving chamber has an interior distributed and provided with hydrogen oscillators made of a magnesium alloy, and the other side of the hydrogen oscillation generating unit is at least connected with an air outlet pipe connected to the receiving chamber, the air outlet pipe has a left end at least connected with a gas nozzle head, the gas nozzle head is at least penetrated with a micro-gas spray orifice connected to the air outlet pipe. 
     The air inlet hole of the present application has a side at least connected with a venturi tube, the venturi tube is provided with a venturi tube hole connected to the air inlet hole, the venturi tube has an upper portion further provided with a flow control valve controlling a diameter of the venturi tube hole, the venturi tube has a side connected with a filter connecting pipe, the filter connecting pipe has a side provided with a socket mounting portion, the socket mounting portion is secured with an air inlet filter. 
     The air inlet hole of the present application has a side at least connected with a filter connecting pipe, the filter connecting pipe has a side provided with a socket mounting portion, the socket mounting portion has an outer edge further provided with an outer threaded section, the socket mounting portion is further provided with a socket which is recessed toward the other side thereof and is connected to the filter connecting pipe, the socket is at least further provided with a stop filtering plate which is inserted into and rests on the other side of the socket, and is further provided with an air inlet filter which presses the stop filtering plate, the other side of the air inlet filter has a periphery further provided with a press ring which cooperates with the socket to press and fix the stop filtering plate, the press ring has a center provided with a filter column protruding rightward, the air inlet filter is further provided with a filter chamber which is recessed from left to right, the filter chamber is filled with a primary filter element, the primary filter element is restricted in the filter chamber by the stop filtering plate, afterwards, a filter pressing ring is rotatably connected with the outer threaded section, the filter pressing ring is further provided with an inner threaded section engaging the outer threaded section, and the filter pressing ring has a right end further provided with a pressing ring resting portion pressing the press ring. 
     The air outlet pipe of the present application has a left end at least connected with a nozzle head socket mounting portion, the nozzle head socket mounting portion has an outer edge further provided with a mounting portion outer threaded section, the nozzle head socket mounting portion is further provided with a nozzle head socket which is recessed toward one side thereof and is connected to the air outlet pipe, a gas nozzle head is inserted into the nozzle head socket, one side of the gas nozzle head has a periphery further provided with a nozzle head press ring inserted into the nozzle head socket, the nozzle head press ring has a center provided with a nozzle head column protruding leftward, the nozzle head column is at least penetrated with a micro-gas spray orifice connected to the air outlet pipe, a nozzle head socket pressing ring is rotatably connected with the mounting portion outer threaded section, the nozzle head socket pressing ring is further provided with a nozzle head socket pressing ring inner threaded section engaging the mounting portion outer threaded section, and the nozzle head socket pressing ring has a left end further provided with a nozzle head socket pressing ring resting portion pressing the nozzle head press ring. 
     In the present application, the price of the hydrogen oscillators made of a magnesium alloy is not high, is available for mass application, and the water molecules contained in the gas do not have the problem of cost, so the cost for performing oscillation to form and separate into oxygen and hydrogen is only limited to that of replacement of the hydrogen oscillators, so the operating cost of the hydrogen microbubbles device is very low. 
    
    
     
       DESCRIPTION OF THE APPENDED DRAWINGS 
         FIG. 1  is a schematic view of a hydrogen microbubbles device of the present application. 
         FIG. 2  is an enlarged schematic view of an air inlet filter of the present application. 
         FIG. 3  is an enlarged schematic view of a gas nozzle head of the present application. 
     
    
    
     In the drawings: 
     A water; A 1  hydrogen microbubbles;  10  hydrogen microbubbles device;  1  air pressurizing assembly;  11  air inlet terminal;  12  air outlet terminal;  13  air inlet unit;  131  air inlet hole;  14  venturi tube;  141  venturi tube hole;  15  flow control valve;  16  filter connecting pipe;  161  socket mounting portion;  162  outer threaded section;  163  socket;  164  stop filtering plate;  165  air inlet filter; 
       166  press ring;  167  filter column;  168  filter chamber;  169  primary filter element;  17  filter pressing ring;  171  inner threaded section;  172  pressing ring resting portion;  2  water container;  3  hydrogen oscillation generating unit;  31  receiving chamber;  32  air outlet pipe;  33  nozzle head socket mounting portion;  331  mounting portion outer threaded section;  332  nozzle head socket;  4  hydrogen oscillators;  34  nozzle head socket pressing ring;  341  nozzle head socket pressing ring inner threaded section;  342  nozzle head socket pressing ring resting portion;  4  hydrogen oscillators;  5  gas nozzle head;  51  gas spray orifice;  52  nozzle head press ring;  53  nozzle head column. 
     DETAILED EMBODIMENT 
     The drawings and the embodiments are associated below to further illustrate the present application, so that the skilled person in this field can better understand and practice the present application, but the examples will not limit the present application. 
     The present application primarily provides a method for manufacturing hydrogen microbubbles, at least comprises an air pressurizing assembly  1 , and at least comprises a water container  2 . 
     The manufacturing method has the steps: 
     step a, the water container  2  contains water A; 
     step b, the air pressurizing assembly  1  sucks and pressurizes a gas to at least enter a hydrogen oscillation generating unit  3 , the hydrogen oscillation generating unit  3  has an interior distributed with hydrogen oscillators  4  made of a magnesium alloy with high activity, the hydrogen oscillators  4  apply a chemical reaction to water molecules contained in the gas to form magnesium oxide and hydrogen, wherein, oxygen in the water molecules chemically reacts with the magnesium alloy to form the magnesium oxide and release the hydrogen; 
     step c, the hydrogen oscillation generating unit  3  drives the gas after the chemical reaction to pass a gas nozzle head  5  which injects the gas into the water A, and the gas nozzle head  5  is at least provided with a micro-gas spray orifice  51  penetrating therethrough, the gas after oscillation passes the micro-gas spray orifice  51  and is injected into the water A to form hydrogen microbubbles A 1  which contains hydrogen with a high hydrogen content (for example: as shown  FIG. 1 ). 
     A hydrogen microbubbles device  10  of the present application at least comprises an air pressurizing assembly  1 , the air pressurizing assembly  1  at least includes an air inlet terminal  11  and an air outlet terminal  12 , one side of the air inlet terminal  11  is at least connected with an air inlet unit  13 , the air inlet unit  13  is at least provided with an air inlet hole  131  penetrating the air inlet terminal  11 , then, the air outlet terminal  12  is at least connected with a hydrogen oscillation generating unit  3 , the hydrogen oscillation generating unit  3  has an interior provided with a receiving chamber  31  connected to the air outlet terminal  12 , the receiving chamber  31  has an interior distributed and provided with hydrogen oscillators  4  made of a magnesium alloy, and the other side of the hydrogen oscillation generating unit  3  is at least connected with an air outlet pipe  32  connected to the receiving chamber  31 , the air outlet pipe  32  has a left end at least connected with a gas nozzle head  5 , the gas nozzle head  5  is at least penetrated with a micro-gas spray orifice  51  connected to the air outlet pipe  32  (as shown  FIG. 1 ). 
     The air inlet hole  131  of the present application has a side at least connected with a venturi tube  14  which contains the previously oscillated gas which contains water molecules, the venturi tube  14  is provided with a venturi tube hole  141  connected to the air inlet hole  131 , in addition, the venturi tube  14  has an upper portion further provided with a flow control valve  15  controlling a diameter of the venturi tube hole  141 , the venturi tube  14  has a side connected with a filter connecting pipe  16 , the filter connecting pipe  16  has a side provided with a socket mounting portion  161 , the socket mounting portion  161  has an outer edge further provided with an outer threaded section  162 , the socket mounting portion  161  is further provided with a socket  163  which is recessed toward the other side thereof and is connected to the filter connecting pipe  16 , the socket  163  is at least further provided with a stop filtering plate  164  which is inserted into and rests on the other side of the socket  163 , and is further provided with an air inlet filter  165  which presses the stop filtering plate  164 , the other side of the air inlet filter  164  has a periphery further provided with a press ring  166  which cooperates with the socket  163  to press and fix the stop filtering plate  164 , the press ring  166  has a center provided with a filter column  167  protruding rightward, the air inlet filter  167  is further provided with a filter chamber  168  which is recessed from left to right, the filter chamber  168  is filled with a primary filter element  169 , the primary filter element  169  is restricted in the filter chamber  168  by the stop filtering plate  164 , afterwards, a filter pressing ring  17  is rotatably connected with the outer threaded section  162 , the filter pressing ring  17  is further provided with an inner threaded section  171  engaging the outer threaded section  162 , and the filter pressing ring  17  has a right end further provided with a pressing ring resting portion  172  pressing the press ring  166  (as shown  FIG. 2 ). 
     The air outlet pipe  32  of the present application has a left end at least connected with a nozzle head socket mounting portion  33 , the nozzle head socket mounting portion  33  has an outer edge further provided with a mounting portion outer threaded section  331 , the nozzle head socket mounting portion  33  is further provided with a nozzle head socket  332  which is recessed toward one side thereof and is connected to the air outlet pipe  32 , a gas nozzle head  5  is inserted into the nozzle head socket  332 , one side of the gas nozzle head  5  has a periphery further provided with a nozzle head press ring  52  inserted into the nozzle head socket  332 , the nozzle head press ring  52  has a center provided with a nozzle head column  53  protruding leftward, the nozzle head column  53  is at least penetrated with a micro-gas spray orifice  51  connected to the air outlet pipe  32 , a nozzle head socket pressing ring  34  is rotatably connected with the mounting portion outer threaded section  331 , the nozzle head socket pressing ring  34  is further provided with a nozzle head socket pressing ring inner threaded section  341  engaging the mounting portion outer threaded section  331 , and the nozzle head socket pressing ring  34  has a left end further provided with a nozzle head socket pressing ring resting portion  342  pressing the nozzle head press ring  52  (as shown  FIG. 3 ). 
     The hydrogen oscillators  4  of the present application are made of a magnesium alloy in the hydrogen oscillation generating unit  3 , the hydrogen oscillators  4  apply a chemical reaction to the water molecules contained in the gas to form magnesium oxide and hydrogen, then, the hydrogen oscillation generating unit  3  drives the gas after the chemical reaction to pass the gas nozzle head  5  which injects the gas into the water A, so that the water A contains the hydrogen microbubbles A 1  with a high hydrogen content. The price of the hydrogen oscillators  4  made of a magnesium alloy is not high, is available for mass application, and the water molecules contained in the gas do not have the problem of cost, so the cost for performing a chemical reaction to form magnesium oxide and hydrogen is only limited to that of replacement of the hydrogen oscillators  4 , so the operating cost of the hydrogen microbubbles device  10  is reduced to the minimum which is the advantage thereof. 
     The abovementioned embodiment is only a preferred embodiment that fully illustrates the present application, the protected range of the present application is not limited to it. The replacement or change made by a skilled person in this field on the basis of the present application will fall within the protected scope of the present application. The protected scope of the present application is based on the claims 
     INDUSTRIAL APPLICABILITY 
     A method for manufacturing hydrogen microbubbles and the device thereof provided by the embodiment of the present application are in that, the price of the hydrogen oscillators made of a magnesium alloy is not high, is available for mass application, and the water molecules contained in the gas do not have the problem of cost, so the cost for performing oscillation to form and separate into oxygen and hydrogen is only limited to that of replacement of the hydrogen oscillators, so the operating cost of the hydrogen microbubbles device is very low. Thus, there is industrial applicability.