CN113634209A - High-energy active ion generating device and using method thereof - Google Patents

Abstract

The invention relates to a high-energy active ion generating device and a using method thereof, wherein the high-energy active ion generating device comprises a cavity, an air supply assembly, an ion generating module, a secondary high-pressure generator and a medium source container, wherein the air supply assembly and the ion generating module are arranged in the cavity; the secondary high voltage generator and the medium source container respectively provide secondary high voltage and medium; the medium flows into the ion generation module and is converted into high-energy active ions to form high-flux atomized liquid drops, and the atomized liquid drops are suitable for killing germs and degrading organic pollutants. The device has simple structure, convenient disassembly, low production cost and convenient maintenance; the device generates the vaporous high-energy active ions by using a medium (such as water) through the comprehensive action of secondary high voltage and micropores, can achieve the effects of degrading organic pollutants and killing germs, and cannot generate secondary pollution.

Description

High-energy active ion generating device and using method thereof

Technical Field

The invention relates to the field of degradation of organic pollutants, in particular to a high-energy active ion generating device capable of being used for killing germs or degrading organic pollutants and a using method thereof.

Background

With the development of synthetic chemistry, a great deal of organic pollutants including dyes, pesticides, bactericides, insecticides and the like are used in daily life, and great threats are brought to the environment and human health. Meanwhile, new chemical substances are continuously introduced into the environment, and environmental pollution caused by refractory organic substances is also increasingly a challenging multidisciplinary problem. Although the innovative organic pollutant degradation technologies such as photocatalysis technology and nanotechnology are more and more diversified, other secondary pollution is introduced in the using process with great risk, for example, the introduction of a nano catalyst in the nanocatalysis degradation technology can generate new pollution. Therefore, how to degrade organic pollutants rapidly, efficiently and especially cleanly becomes a problem to be solved urgently.

In the existing high-energy active ion generation technology, various high-pressure micro-spraying devices also exist. For example, patent application No. 202010335698.8 discloses a nano water ion atomized liquid and an electrostatic atomization device, wherein the nano water ion atomized liquid is obtained by high-pressure electrostatic atomization and has the functions of disinfection, deodorization and the like, but the nano water ions have an acidic function and are harmful to human skin. In addition, in order to increase the printing and dyeing/printing effect, some high-pressure micro-spraying technologies are also adopted, for example, patent application No. 201510037696.

Under the environment of normal temperature and pressure, the medium (such as water) is utilized to generate the mist high-energy active ions under the combined action of the secondary high voltage and the micropores to degrade the organic pollutants, and the method is a quick, efficient and especially clean method. However, the manufacturing process of the micropores in this method has a difficulty, and the generated ions also have a problem of small flux. The inventor finds out through experiments that the device developed based on the method has poor stability, and the application of the method is severely limited. Based on this, if a device with high flux, strong practicability and good stability can be developed, great convenience can be provided for daily life and production.

Disclosure of Invention

In order to solve the above problems, the present invention provides a high-energy active ion generator with simple structure and flexible layout, which can degrade organic pollutants by using a medium such as water to generate fog-like high-energy active ions through the combined action of secondary high voltage and micropores, and does not generate secondary pollution.

In order to achieve the purpose, the technical scheme of the invention is as follows:

a high-energy active ion generating device comprises a cavity, an air supply assembly, an ion generating module, a secondary high-pressure generator and a medium source container, wherein the air supply assembly and the ion generating module are arranged in the cavity;

wherein the high voltage generator and the medium source container respectively provide a second highest voltage and a medium; the medium flows into the ion generation module and is converted into high-energy active ions, atomized liquid drops containing the high-energy ions are formed at high flux, and the high-energy ions in the atomized liquid drops are suitable for killing germs and degrading organic pollutants.

Furthermore, the ion generation module comprises a plastic vent valve, a guide pipe, a medium storage container cover, a sealing ring, a medium storage container, a three-way connector, a microporous pipe, a metal wire, an insulating sleeve, an electrode clamping seat, an electrode plate and a sealing connection assembly;

the plastic vent valve and the guide pipe are respectively connected with the medium storage container cover, the medium storage container cover is connected with the medium storage container, the microporous pipe is positioned at the lower port of the three-way connector, the head of the metal wire extends into the microporous pipe from the side port of the three-way connector, and the insulating sleeve plays an insulating role in the metal wire;

the electrode clamping seat comprises a plurality of metal wires, wherein the tail parts of the three metal wires are connected with a lead in a welding mode, then the tail parts of the three metal wires are welded to one position with the tail part of the fourth metal wire, and finally the tail parts of the three metal wires are connected with the secondary high-voltage generator through the lead, each welding position is insulated by a heat-shrinkable tube, a circular groove is formed in the lower end face of the electrode clamping seat, and the electrode plate is located in the circular groove.

Further, sealing connection subassembly includes that connecting bolt, first sealed pad, second are sealed fills up, the sealed pad of third, sealed spiral shell head, first locking spiral shell head and second locking spiral shell head, and first sealed pad, the sealed pad of second are placed respectively the both sides of medium storage container bottom through-hole, connecting bolt pass first sealed pad, medium storage container bottom through-hole and the sealed pad of second in proper order, and the sealed pad of third, sealed spiral shell head, first locking spiral shell head are installed in proper order the lower port of tee bend interface, second locking spiral shell head is connected with tee bend interface's side port through the screw thread.

Further, the cavity is provided with a cavity frame, a cavity cover and a cavity base, the electrode clamping seat is fixed at the tail part of the cavity frame, and the cavity base is connected with the cavity frame through a screw and fixes the electrode clamping seat and the electrode plate.

Further, an annular groove is formed in the upper end face of the medium storage container, the sealing ring is placed in the annular groove, the medium storage container cover is connected with the medium storage container through a screw, and the first sealing gasket is extruded, so that the medium storage container is sealed.

Furthermore, the third sealing gasket is placed inside the lower port of the three-way connector, the sealing screw head is connected with the lower port of the three-way connector through threads, and the sealing gasket is extruded to achieve a sealing effect; the micropore pipe is placed inside the sealed screw head, and the first locking screw head is connected with the sealed screw head through threads to clamp and position the micropore pipe.

Furthermore, the head of the metal wire extends into the microporous tube from the side port of the three-way connector, and the height of the head of the metal wire in the microporous tube is adjusted through the second locking screw head.

Furthermore, the number of the three-way interfaces is more than one, each three-way interface comprises three intercommunicated ports, one end of each three-way interface is connected with the medium, the other end of each three-way interface is connected with the secondary high voltage, and the other end of each three-way interface is connected with the microporous tube.

Further, the aperture range of the microporous tube is 0.1-100 μm; the outer diameter range of the metal wire is 1-100 mu m, and the metal wire is made of silver, copper, aluminum, iron or platinum;

the secondary high voltage generator generates positive or negative secondary high voltage with the voltage value of +/-2 kV-10 kV.

In addition, the use method of the high-energy active ion generating device mainly comprises the following steps:

when the medium storage container is filled with the medium, the medium flows into the three-way interface from the internal through hole of the connecting bolt and then flows into the microporous pipe; meanwhile, the secondary high voltage is generated by the secondary high voltage generator, is transmitted to the metal wire through the conducting wire and then is transmitted to the medium of the microporous tube through the metal wire, atomized liquid drops ejected out at high speed (250-300 m/s) can be continuously generated at the conical opening of the microporous tube, firstly, electric energy is firstly converted into kinetic energy and surface energy to enable the liquid to be broken into high-speed tiny liquid drops, the tiny liquid drops with high kinetic energy and high surface energy are firstly separated from the medium, and secondly, the tiny liquid drops with high kinetic energy and high surface energy are in friction collision with the air medium to enable the high kinetic energy and high surface energy to be converted into chemical energy to generate ions with high chemical energy. The high-energy ion clusters exist in the micro-droplets and act on the surface of the liquid or the solid, so that organic pollutants in the solution and on the surface of the solid are degraded, and germs are killed. Meanwhile, an air supply assembly is arranged above the ion generation module, so that the spraying distance is increased.

The invention has the beneficial effects that: the invention converts neutral media such as water (purified water, alcohol and the like) into high-energy active ions through the technical combination of sub-high voltage and micropores, wherein the high-energy active ions are water cluster hydroxyl radicals, water radical cation clusters, negative oxygen ion clusters, hydronium ions and the like, and the ions have the functions of degrading organic pollutants and disinfecting and sterilizing. Wherein, the used secondary high voltage range is +/-2 kV-10 kV, the current is about hundreds of nanoamperes (nA) level, the aperture range of the micropore is between 0.1 μm and 100 μm, and the energy consumption is low, and the safety is good. Therefore, the pollution-free high-energy active ions can be quickly obtained at normal temperature and normal pressure with low cost and low power consumption, thereby achieving the purposes of disinfection and sterilization and degrading organic pollutants. Is especially suitable for high-flux disinfection, sterilization and degradation of multiple people.

Although in the field of mass spectrometry, the combined action of secondary high voltage and a nozzle is used for generating ions of an object to be detected for detecting the object to be detected; and in the textile field, high-pressure micro-spraying technology is used for printing/printing and dyeing purposes; however, in the aspect of degrading organic pollutants, the invention proposes to use atomized high-energy active ions to degrade, disinfect and sterilize for the first time.

Compared with the prior art for degrading organic pollutants by high-energy ions, the method has the characteristics of high energy consumption (such as large energy requirements of laser, X-ray, ultraviolet light and the like), poor safety and easy secondary pollution (such as chemical reagents such as hydrogen peroxide, chlorine dioxide, sodium sulfite, iron dichloride and the like are required to be added).

Compared with the existing ionization technology, such as electrostatic atomization technology, which uses high voltage and micro-spray technology, the voltage is generally very high, some voltages are even hundreds of thousands of volts, the energy consumption is high, the safety is poor, and meanwhile, the used micropores are generally large and are generally hundreds of micrometers. The sub-high voltage range used in the present invention is + -2 kV-10 kV, the current is about several hundred nanoamperes (nA) level, and the pore diameter range of the micropores is between 0.1 μm and 100 μm.

Drawings

FIG. 1 is a schematic diagram of the system components of the apparatus of the present invention;

FIG. 2 is a perspective view of the apparatus of the present invention;

FIG. 3 is an exploded view of the various modules of the apparatus of the present invention;

FIG. 4 is a cross-sectional view of the device of the present invention;

FIG. 5 is an exploded view of an ion generating module;

fig. 6 is a schematic structural diagram of the three-way interface.

Wherein the various components are labeled as follows: a cavity 1; a cavity frame 11; a cavity cover 12; a cavity base 13; an air supply assembly 2; a secondary high voltage generator 3; an ion generation module 4; a medium source container 5; a plastic breather valve 41; a conduit 42; a media storage container lid 43; a seal ring 44; a media storage container 45; a connecting bolt 46; a first seal gasket 47; a second seal 48; a three-way interface 49; a third gasket 410; a sealing screw head 411; a first locking screw head 412; a microporous tube 413; a wire 414; a second locking screw 415; an insulating sleeve 416; an electrode holder 417; and an electrode pad 418.

Detailed Description

As shown in fig. 1 to fig. 6, a high-energy active ion generating device is characterized by comprising a cavity 1, an air supply assembly 2 arranged in the cavity 1, an ion generating module 4, a secondary high-voltage generator 3 connected with the cavity 1, and a medium source container 5;

wherein the secondary high voltage generator 3 and the medium source container 5 provide a secondary high voltage and a medium, respectively; the medium flows into the ion generation module 4 and is converted into high-energy active ions to form high-flux atomized liquid drops, and the atomized liquid drops are suitable for killing germs and degrading organic pollutants.

The ion generation module 4 comprises a plastic vent valve 41, a conduit 42, a medium storage container cover 43, a sealing ring 44, a medium storage container 45, a three-way joint 49, a microporous pipe 413, a metal wire 414, an insulating sleeve 416, an electrode clamping seat 417, an electrode slice 418 and a sealing connection assembly;

the plastic vent valve 41 and the conduit 42 are respectively connected with the medium storage container cover 43, the medium storage container cover 43 is connected with the medium storage container 45, the microporous tube 413 is positioned at the lower port of the three-way connector 49, the head of the metal wire 414 extends into the microporous tube 413 from the side port of the three-way connector 49, and the insulating sleeve 416 plays an insulating role in insulating the metal wire 414;

the number of the metal wires 414 is multiple, for example, the number of the metal wires 414 is four, when the metal wires 414 are installed, the tails of three metal wires 414 are connected with a lead by welding, then welded to one place with the tail of a fourth metal wire 414, and finally connected with the secondary high voltage generator 3 by a lead, each welding place is insulated by a heat shrink tube, a circular groove is formed on the lower end face of the electrode clamping seat 417, and the electrode plate 418 is located in the circular groove.

Further, sealing connection subassembly includes connecting bolt 46, first sealed 47, the second sealed pad 48, the third sealed pad 410, sealed spiral shell head 411, first locking spiral shell head 412 and second locking spiral shell head 415, and first sealed 47, the second sealed pad 48 of filling up are placed respectively the both sides of medium storage container 45 bottom through-hole, connecting bolt 46 pass through first sealed 47, the through-hole and the second sealed pad 48 of medium storage container 45 bottom in proper order, and the third sealed pad 410, sealed spiral shell head 411, first locking spiral shell head 412 are installed in proper order the lower port of three way connection 49, second locking spiral shell head 415 is connected with three way connection 49's side port through the screw thread.

The cavity 1 is provided with a cavity frame 11, a cavity cover 12 and a cavity base 13, the electrode clamping seat 417 is fixed at the tail part of the cavity frame 11, and the cavity base 13 is connected with the cavity frame 11 through a screw and fixes the electrode clamping seat 417 and the electrode plate 418.

In addition, the air supply assembly 2 can adopt a fan structure, and is arranged below the cavity cover 12 and right above the ion generation module 4, and the cavity cover 12 is provided with a plurality of through holes, so that air can be conveniently supplied to the ion generation module 4 through the air supply assembly 2, and the spraying distance can be adjusted.

The specific mounting details of the various components are as follows: the upper end surface of the medium storage container 45 is provided with an annular groove, the packing ring 44 is placed in the annular groove, and the medium storage container cover 43 is connected to the medium storage container 44 by a screw, and presses the first packing 47, thereby sealing the medium storage container 44.

The third sealing gasket 410 is placed inside the lower port of the three-way connector 49, the sealing screw head 411 is connected with the lower port of the three-way connector 49 through threads, and the third sealing gasket 410 is extruded to achieve a sealing effect; the micropore pipe 413 is placed inside the sealing screw head, and the first locking screw head 412 is connected with the sealing screw head 411 through threads to clamp and position the micropore pipe 413.

The head of the wire 414 extends into the interior of the microporous tube 413 from the side port of the three-way connector 49, and the height of the head of the wire 414 in the microporous tube 413 is adjusted by the second locking screw 415.

The number of the three-way interfaces 49 is more than one, and the three-way interfaces 49 comprise three intercommunicated ports, one end of each port is connected with the medium, the other end of each port is connected with the secondary high voltage, and the other end of each port is connected with the microporous tube.

In this embodiment, the diameter of the microporous tube 413 is in the range of 0.1 μm to 100 μm; the outer diameter of the metal wire 414 is in the range of 1 μm to 100 μm, and the material thereof is silver, copper, aluminum, iron or platinum; the sub-high voltage generator 3 generates a positive or negative sub-high voltage having a voltage value of + -2 kV-10 kV.

The working principle of the device is as follows: when the medium storage container 45 is filled with the medium, the medium flows into the three-way connector 49 from the internal through hole of the connecting bolt 46 and then flows into the microporous tube 413; meanwhile, the secondary high voltage generator 3 generates secondary high voltage, the secondary high voltage is transmitted to the metal wire 414 through a lead and then transmitted to a medium of the microporous pipe 413 through the metal wire 414, a large amount of high-energy active ions are generated in the microporous pipe 413, the electrode plate 418 below the microporous pipe 413 is connected with a ground wire, an electric field is formed between the microporous pipe 413 and the electrode plate 418, atomized liquid drops are continuously generated at the conical opening of the microporous pipe 413, the atomized liquid drops play roles in killing germs and degrading organic pollutants, and meanwhile, the air supply assembly 2 is installed above the ion generation module 4, so that the spraying distance is increased.

It will be understood by those skilled in the art that these examples are given for illustrative purposes only and are not intended to limit the scope of the present invention, and that various equivalent modifications and changes may be made thereto without departing from the scope of the present disclosure.

Claims (10)

1. The high-energy active ion generating device is characterized by comprising a cavity (1), an air supply assembly (2) arranged in the cavity (1), an ion generating module (4), a secondary high-voltage generator (3) connected with the cavity (1) and a medium source container (5);

wherein the secondary high voltage generator (3) and the medium source container (5) provide a secondary high voltage and a medium, respectively; the medium flows into the ion generation module (4) and is converted into high-energy active ions, atomized liquid drops containing the high-energy ions are formed at high flux, and the high-energy ions in the atomized liquid drops are suitable for killing germs and degrading organic pollutants.

2. The high-energy active ion generating device according to claim 1, wherein the ion generating module (4) comprises a plastic vent valve (41), a conduit (42), a medium storage container cover (43), a sealing ring (44), a medium storage container (45), a three-way joint (49), a microporous tube (413), a metal wire (414), an insulating sleeve (416), an electrode clamping seat (417), an electrode plate (418) and a sealing connecting assembly;

the plastic vent valve (41) and the conduit (42) are respectively connected with the medium storage container cover (43), the medium storage container cover (43) is connected with the medium storage container (45), the microporous tube (413) is positioned at the lower port of the three-way port (49), the head of the metal wire (414) extends into the microporous tube (413) from the side port of the three-way port (49), and the insulating sleeve (416) plays an insulating role on the metal wire (414);

the number of the metal wires (414) is multiple, wherein the tails of three metal wires (414) are connected with a lead in a welding mode, then the tails of three metal wires (414) are welded to one position, and finally the tails of three metal wires are connected with the secondary high-voltage generator (3) through a lead, each welding position is insulated by a heat-shrinkable tube, the lower end face of the electrode clamping seat (417) is provided with a circular groove, and the electrode plate (418) is positioned in the circular groove.

3. An energetic active ion generating device according to claim 2, the sealing and connecting assembly comprises a connecting bolt (46), a first sealing gasket (47), a second sealing gasket (48), a third sealing gasket (410), a sealing screw head (411), a first locking screw head (412) and a second locking screw head (415), wherein the first sealing gasket (47) and the second sealing gasket (48) are respectively arranged at two sides of a through hole at the bottom of the medium storage container (45), the connecting bolt (46) sequentially penetrates through the first sealing gasket (47), the through hole at the bottom of the medium storage container (45) and the second sealing gasket (48), and the third sealing gasket (410), the sealing screw head (411) and the first locking screw head (412) are sequentially arranged at a lower port of the three-way interface (49), the second locking screw head (415) is connected with a side port of the three-way interface (49) through threads.

4. The high-energy active ion generating device according to claim 2 or 3, wherein the cavity (1) is provided with a cavity frame (11), a cavity cover (12) and a cavity base (13), the electrode clamping seat (417) is fixed at the tail part of the cavity frame (11), and the cavity base (13) is connected with the cavity frame (11) through a screw and fixes the electrode clamping seat (417) and the electrode plate (418).

5. A high energy active ion generating device according to claim 2 or 3, wherein the upper end surface of the medium storage container (45) is provided with an annular groove, the sealing ring (44) is placed in the annular groove, the medium storage container cover (43) is connected with the medium storage container (44) through a screw, and the first sealing gasket (47) is pressed to seal the medium storage container (44).

6. The high-energy active ion generating device according to claim 3, wherein the third sealing gasket (410) is placed inside the lower port of the three-way connector (49), the sealing screw head (411) is connected with the lower port of the three-way connector (49) through threads, and the third sealing gasket (410) is squeezed to achieve a sealing effect; the micropore pipe (413) is placed inside the sealing screw head, and the first locking screw head (412) is connected with the sealing screw head (411) through threads to clamp and position the micropore pipe (413).

7. A high-energy active ion generating device according to claim 3, wherein the head of the wire (414) extends into the interior of the microporous tube (413) from the side port of the three-way connector (49), and the height of the head of the wire (414) in the microporous tube (413) is adjusted by the second locking screw head (415).

8. The high-energy active ion generating device according to claim 3, wherein the number of the three-way interfaces (49) is more than one, and the three-way interfaces (49) comprise three intercommunicated ports, one end of each three-way interface is connected with the medium, the other end of each three-way interface is connected with the secondary high voltage, and the other end of each three-way interface is connected with the microporous tube.

9. The energetic active ion generating device according to claim 3, characterized in that the caliber of the microporous tube (413) ranges from 0.1 μm to 100 μm;

the outer diameter range of the metal wire (414) is 1-100 mu m, and the metal wire is made of silver, copper, aluminum, iron or platinum;

the secondary high voltage generator (3) generates positive or negative secondary high voltage with the voltage value of +/-2 kV-10 kV.

10. The use method of the high-energy active ion generating device is characterized by comprising the following steps:

when the medium storage container (45) is filled with the medium, the medium flows into the three-way interface (49) from the internal through hole of the connecting bolt (46) and then flows into the microporous pipe (413); meanwhile, the secondary high voltage generator (3) generates secondary high voltage, the secondary high voltage is transmitted to the metal wire (414) through a lead, and then is transmitted to a medium of the microporous tube (413) through the metal wire (414), a large number of high-energy active ions are generated in the microporous tube (413), the electrode plate (418) below the microporous tube (413) is connected with the ground wire, an electric field is formed between the microporous tube (413) and the electrode plate (418), atomized liquid drops can be continuously generated at the conical opening of the microporous tube (413), the atomized liquid drops play roles in killing germs and degrading organic pollutants, meanwhile, the air supply assembly (2) is installed above the ion generation module (4), and the spraying distance is increased.

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