WO2017008692A1 - Particle flow generation device, method, emitter structure, preparation method, drive circuit and purifier - Google Patents

Abstract

A high-energy negative oxygen ion particle flow generation device (10) comprises an emitter (16) and a negative high-voltage acceleration electric field generator (182). The emitter comprises emitting pins (160b) in an array. The negative high-voltage acceleration electric field generator is connected to the emitter, and is configured to provide the emitter a negative high voltage to enable the tip of each emitting pin to have corona discharge, so as to form negative oxygen ions. The emitter employs emitting pins in an array, and therefore, the emission of negative oxygen ions is no longer from a single point but a surface, such that the number of negative oxygen ions in a certain space is increased, thus raising the concentration of negative oxygen ions. In addition, the emitter is connected to the negative high-voltage acceleration electric field generator, such that the negative oxygen ions gain higher energy in the acceleration electric field. Also provided is a particle flow method, emitter structure, preparation method, drive circuit and purifier.

Description

Particle flow generating device, method, emitter structure, manufacturing method, driving circuit, purifier

Priority information

This application requests the Chinese national knowledge submitted to the State Intellectual Property Office of China on July 10, 2015, and the patent application numbers are 2015104047302, 201510408064X, 2015104050235, 2015104043744, 2015104048663, 2015205032530, 2015204991249, 2015205026811, 201520499411X, 2015204991234, and July 13, 2015. The priority and benefit of the patent application, which is hereby incorporated by reference in its entirety in its entirety in its entirety in the the the the the the the the the the the

Technical field

The invention relates to the field of air purification and health care, and in particular to a particle flow generating device, a method, a transmitter structure, a manufacturing method, a driving circuit and a purifier.

Background technique

The negative oxygen ions generated by the existing negative oxygen ion generating technology and device have low energy, low concentration and small amount. High energy, high concentration, small particle size, and cosine propagation type, which are not easily absorbed by the human body and do not meet medical requirements, and are mostly accompanied by negative pollutants.

Summary of the invention

The present invention aims to solve at least one of the technical problems existing in the prior art. To this end, the present invention needs to provide a particle flow generating device, method, emitter structure, manufacturing method, driving circuit, and purifier.

A high energy negative oxygen ion particle flow generating device according to an embodiment of the present invention includes:

a transmitter comprising an array of firing pins; and

A negative high voltage accelerating electric field generator coupled to the transmitter, the negative high voltage accelerating electric field generator for providing the emitter negative high voltage voltage to cause each of the firing pin tips to corona discharge to form negative oxygen ions.

In the high-energy negative oxygen ion particle flow generating device of the embodiment of the present invention, since the emitter adopts an array type emitting needle, the negative oxygen ion emission is no longer a point but a surface, and the negative oxygen ions in a certain space The amount is increased to increase the concentration of the negative oxygen ions. And the emitter is connected to the negative high voltage accelerating electric field generator, and the negative oxygen ions can obtain higher energy under the acceleration electric field.

In some embodiments, the high-energy negative oxygen ion particle flow generating device includes a housing that houses the emitter, the left and right sides of the housing are formed with an air inlet, and the upper side of the housing is formed with a first air outlet. The front side of the outer casing is formed with a second air outlet.

In some embodiments, a fan and an air duct are housed in the outer casing, and the fan is disposed in the air duct, and the air duct is configured to guide the gas sucked from the air inlet to the first air outlet and The second air outlet.

In some embodiments, the air duct is substantially in an inverted R shape, and the air duct includes a receiving portion that accommodates the fan, an air guiding portion that communicates with the receiving portion and is located above the receiving portion, and a A air blowing window that communicates with the air guiding portion and the first air outlet, and a top surface of the air channel is formed with an air blowing port that communicates with the second air outlet.

In some embodiments, a front side of the air duct is formed with a first fixing plate below the air blowing window, and a top surface of the air channel is formed with a second fixing plate, the rear of the first fixing plate The emitter is fixed to the side of the first air outlet, and the emitter is fixed to the emitter of the second air outlet.

In some embodiments, a filter system is provided on the front and rear sides of the outer casing to filter the gas drawn in by the air inlet.

In some embodiments, the negative high voltage voltage is modulated with a human physiological life cosine wave for health care rehabilitation and disease treatment.

In some embodiments, the negative high voltage voltage has a voltage oscillation frequency of less than 20 KHz.

In some embodiments, the negative high voltage voltage has a voltage value between -0.6 and -25,000 volts.

In some embodiments, the voltage of the negative high voltage is used between -1.5 and -20,000 volts for health care rehabilitation and disease treatment.

A method of manufacturing a high energy negative oxygen ion particle stream, comprising the steps of:

Providing a transmitter, the transmitter comprising an array of firing pins; and

A negative high voltage voltage is applied to the emitter to cause each of the firing pins to corona discharge to form the high energy negative oxygen ion particle stream.

In some embodiments, the firing pin is a gold plated stainless steel needle.

In some embodiments, the tip of the firing needle is in the shape of a regular cone.

In some embodiments, the method of manufacturing a high energy negative oxygen ion particle stream further comprises a pretreatment of filtering and sterilizing air.

A structure of an area array gold needle negative oxygen ion particle stream emitter, comprising:

At least one firing needle assembly, each of the firing needle assemblies comprising:

a needle holder for connecting to a driving circuit; and

a plurality of firing pins arranged in an array on the needle holder and electrically connected to the needle holder;

The needle holder and the firing pin are covered with a first insulating layer; the emitting pin includes a tip end portion exposed from the first insulating layer for corona discharge to form negative oxygen ions; the needle holder includes The electrode in which the first insulating layer leaks.

In some embodiments, the number of the firing pin assemblies is multiple. The transmitter further includes a conductive metal piece And the high-insulation bearing mounting strips, wherein the plurality of the transmitting pin assemblies are electrically connected by the conductive metal sheets, and the conductive metal sheets are respectively mounted on the high-insulation bearing mounting strips.

In some embodiments, the emitter further includes a second insulating layer that surrounds the exposed portion of the conductive metal sheet.

In some embodiments, the tips of the tip portions are all in the same plane.

In some embodiments, the firing needle conforms to: L/D ≤ 15; wherein L is the needle length of the firing needle and D is the largest diameter of the needle body.

In some embodiments, the needle holder is a PCB board.

A method for manufacturing an arrayed gold needle negative oxygen ion particle flow emitter comprises the following steps:

Providing a plurality of firing pins and a needle holder;

Assembling the plurality of array of emitter pins on the needle holder to form an emitter needle assembly; and

Forming the firing pin assembly to form a first insulating wrap layer, the tip end portion of the emitting pin exposing the first insulating wrap layer to form a negative oxygen ion by corona discharge, and the electrode of the needle holder is exposed The first insulating wrap layer.

In some embodiments, the method for fabricating an area array gold needle negative oxygen ion particle stream emitter further comprises the steps of:

Assembling a plurality of the array of the firing pin assemblies on the conductive metal sheet; and

The conductive metal piece is mounted on the high insulation load bearing strip.

In some embodiments, after the array of the transmitting pin assemblies is assembled, detecting whether each of the transmitting pins is electrically connected to each other, and if conducting, injecting a portion of the conductive metal sheet between the transmitting pin assemblies. Formed to form a second insulating wrap layer.

In some embodiments, the conductive metal piece is soldered to the upper wire terminal, the conductive metal piece is placed on the high insulation load-bearing mounting strip, and the transmitting needle assembly, the conductive metal piece, and the The high-insulation load-bearing mounting strips are connected and fixed.

In some embodiments, each of the firing pins is perpendicular to a plane of the needle holder and each of the firing pins is parallel to each other, the tips of the firing pins being in the same plane.

A driving circuit for a high energy negative oxygen ion particle flow generator, comprising:

a cosine carrier generator for generating a cosine wave;

a negative high voltage accelerating electric field generator coupled to the cosine carrier generator for forming a negative high voltage that varies according to a cosine wave, the high energy negative oxygen ion particle flow generator including an emitter, the negative high voltage accelerating electric field generator and The emitters are coupled to cause the emitter to corona discharge to form negative oxygen ions that vary in accordance with the cosine wave motion law.

In some embodiments, the cosine carrier generator is loaded with a human physiological life cosine wave.

In some embodiments, the fluctuation frequency of the human physiological vital cosine wave is an integer multiple of 60-80 times/min.

In some embodiments, the negative high voltage accelerating electric field generator is coupled to a virtual ground charge balancing network to place the earth As a positive electrode, the negative oxygen ions are radiated from the emitting end of the emitter to the earth.

In some embodiments, the driving circuit is connected with a power input unit, and a protection circuit is connected between the driving circuit and the power input unit to prevent overcurrent and overvoltage of the driving circuit.

In some embodiments, the drive circuit is coupled to a steering circuit for controlling the drive circuit based on user input.

In some embodiments, the high-energy negative oxygen ion particle flow generator is provided with a human-machine interaction interface, and the human-machine interaction interface is connected with the manipulation circuit to artificially regulate the fluctuation frequency of the human physiological life cosine wave.

An off-machine elimination smog and soot air purifier, including:

a main air duct, an air inlet is formed on a rear side of the main air duct, and an air outlet is formed on a front side of the main air duct;

a first fan disposed at the air inlet;

An emitter disposed at the air outlet, the emitter comprising an array of emitting pins, the emitter tip corona discharge forming a negative oxygen ion;

a left deflecting air duct and a right guiding air duct disposed on the left and right sides of the main air duct; and

a second fan disposed in the left guiding air duct and a third fan disposed in the right guiding air duct;

The left guiding air duct, the right guiding air duct, the second fan and the third fan are used to drive a gas flow to form a gas circulation.

In some embodiments, a first filtering device is disposed within the main air duct.

In some embodiments, a left air inlet is formed on a left side of the left air guiding duct, a left air outlet is formed on a front side of the left air guiding duct, and a right side is formed on a right side of the right air guiding duct The right air inlet is formed with a right air outlet on the front side of the right air guiding duct.

In some embodiments, a second filtering device is disposed in the left guiding air duct, the second filtering device is located at the left air inlet, and a third filtering device is disposed in the right guiding air channel. The third filter device is located at the right air inlet.

In some embodiments, the left guiding air duct is symmetrical with the right guiding air duct with respect to the main air duct, and the second wind turbine is symmetric with the third air duct with respect to the main air duct.

In some embodiments, the transmitter is coupled to a negative high voltage accelerating electric field generator for providing the transmitter negative high voltage.

The additional aspects and advantages of the invention will be set forth in part in the description which follows.

DRAWINGS

The above and/or additional aspects and advantages of the present invention will become apparent from the description of the embodiments in conjunction with the accompanying drawings Obvious and easy to understand, where:

1 is a schematic perspective view of a high energy negative oxygen ion particle flow generating device in accordance with an embodiment of the present invention.

2 is an exploded perspective view of a high energy negative oxygen ion particle flow generating device in accordance with an embodiment of the present invention.

3 is another exploded schematic view of a high energy negative oxygen ion particle flow generating device in accordance with an embodiment of the present invention.

4 is a functional block diagram of a high energy negative oxygen ion particle flow generating device in accordance with an embodiment of the present invention.

5 is a perspective view of a duct of a high-energy negative oxygen ion particle flow generating device according to an embodiment of the present invention.

6 is a schematic structural view of a transmitter of a high-energy negative oxygen ion particle flow generating device according to an embodiment of the present invention.

7 is a schematic structural view of a firing needle assembly of a high energy negative oxygen ion particle flow generating device according to an embodiment of the present invention.

8 is a schematic view showing the structure of an emitter needle of a high-energy negative oxygen ion particle flow generating device according to an embodiment of the present invention.

9 is a schematic structural view of a needle holder of a high-energy negative oxygen ion particle flow generating device according to an embodiment of the present invention.

10 is another schematic diagram of a generator assembly of a high energy negative oxygen ion particle flow generating device in accordance with an embodiment of the present invention.

11 is a circuit diagram of a high energy negative oxygen ion particle flow generator in accordance with an embodiment of the present invention.

12 is a schematic plan view of an off-machine elimination smog and soot air purifier according to an embodiment of the present invention.

Figure 13 is a schematic view showing the structure of the external smog and soot air purifier in a plan view according to an embodiment of the present invention.

detailed description

The embodiments of the present invention are described in detail below, and the examples of the embodiments are illustrated in the drawings, wherein the same or similar reference numerals are used to refer to the same or similar elements or elements having the same or similar functions. The embodiments described below with reference to the accompanying drawings are intended to be illustrative of the invention and are not to be construed as limiting.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "transverse", "length", "width", "thickness", "upper", "lower", "front", " Orientations of "post", "left", "right", "vertical", "horizontal", "top", "bottom", "inside", "outside", "clockwise", "counterclockwise", etc. The positional relationship is based on the orientation or positional relationship shown in the drawings, and is merely for the convenience of the description of the present invention and the simplified description, and is not intended to indicate or imply that the device or component referred to has a specific orientation, and is constructed and operated in a specific orientation. Therefore, it should not be construed as limiting the invention. Moreover, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, features defining "first" or "second" may include one or more of the described features either explicitly or implicitly. In this In the description of the invention, the meaning of "a plurality" is two or more, unless specifically defined otherwise.

In the description of the present invention, it should be noted that the terms "installation", "connected", and "connected" are to be understood broadly, and may be fixed or detachable, for example, unless otherwise explicitly defined and defined. Connected, or connected in one piece. It can be a mechanical connection or an electrical connection. It can be directly connected or indirectly connected through an intermediate medium, which can be the internal communication of two elements or the interaction of two elements. For those skilled in the art, the specific meanings of the above terms in the present invention can be understood on a case-by-case basis.

In the present invention, the first feature "on" or "under" the second feature may include direct contact of the first and second features, and may also include first and second features, unless otherwise specifically defined and defined. It is not in direct contact but through additional features between them. Moreover, the first feature "above", "above" and "above" the second feature includes the first feature directly above and above the second feature, or merely indicating that the first feature level is higher than the second feature. The first feature "below", "below" and "below" the second feature includes the first feature directly above and above the second feature, or merely the first feature level being less than the second feature.

The following disclosure provides many different embodiments or examples for implementing different structures of the present invention. In order to simplify the disclosure of the present invention, the components and arrangements of the specific examples are described below. Of course, they are merely examples and are not intended to limit the invention. In addition, the present invention may be repeated with reference to the numerals and/or reference numerals in the various examples, which are for the purpose of simplicity and clarity, and do not indicate the relationship between the various embodiments and/or arrangements discussed. Moreover, the present invention provides examples of various specific processes and materials, but one of ordinary skill in the art will recognize the use of other processes and/or the use of other materials.

Referring to FIG. 1 to FIG. 4 , a high-energy negative oxygen ion particle flow generating device 10 according to an embodiment of the present invention includes a housing 12 and an air handler 14 , a transmitter 16 , a driving circuit 18 , a protection circuit 20 , and a housing 16 . The circuit 22 is controlled.

In this embodiment, the outer casing 12 is substantially rectangular and includes a bottom plate 121, a top plate 123 disposed parallel to the bottom plate 121, and a front side plate 125 extending from the edge of the bottom plate 121 and connecting the bottom plate 121 and the top plate 123, the rear side plate 127, and the left side. Side plate 129 and right side plate 12a. In this manner, the bottom plate 121, the top plate 123, the front side plate 125, the rear side plate 127, the left side plate 129, and the right side plate 12a are enclosed to constitute the accommodating space 12b. The air processor 14 , the transmitter 16 , the driving circuit 18 , the protection circuit 20 , and the control circuit 22 are received in the receiving space 12 b , wherein the driving circuit 18 , the protection circuit 20 , and the control circuit 22 can be formed on one circuit board or multiple circuits On the board.

The outer casing 12 is formed with an air inlet 120 and an air outlet 122. In the present embodiment, the air inlet 120 is formed on the left side plate 129 and the right side plate 12a. Specifically, the air inlet 120 includes an elongated opening formed on the left side plate 129 and adjacent to the front side plate 125 and the rear side plate 127, and the longitudinal direction of the elongated opening is substantially perpendicular to the bottom plate 121. The air outlet 122 is formed on the front side plate 125 and the top plate 123. Specifically, the air outlet 122 includes a substantially rectangular first air outlet 122a formed on the front side plate 125 near the top plate 123 and a basic moment formed on the top plate 123 near the front side plate 125. The second air outlet 122b.

The air handler 14 includes a blower system 142 and a filtration system 140. The air supply system 142 is disposed between the air inlet 120 and the air outlet 122 for establishing a flow path between the air inlet 120 and the air outlet 122 and sucking gas through the air inlet 120 to be sent out from the air outlet 122 through the air channel. The filter system 140 is disposed between the air inlet 120 and the air supply system 142 for the gas sucked in by the pre-filtered air inlet 120.

In the present embodiment, the shape and position of the air inlet 120 and the air outlet 124 are corresponded. The air supply system 142 is vertically disposed at an intermediate position of the outer casing 12. The number of the filter systems 140 is two, and is disposed between the elongated opening adjacent to the front side panel 125 and the air supply system 140, and between the elongated opening of the rear side panel 127 and the air supply system 142. The filtration system 140 includes a first filter layer 140a, a second filter layer 140b, and a third filter layer 140c that are sequentially disposed along the flow direction of the airflow.

In the present embodiment, the first filter layer 140a is used for removing formaldehyde, and a composite mesh of granular activated carbon and acetal is used. The second filter layer 140b is used to decompose organic harmful gases, and photocatalyst and multi-catalyst technology can be used. The third filter layer 140c is used for sterilization, and the bacterial virus can be killed by the 253.7 nm ultraviolet technology. In this way, the air entering the high-energy negative oxygen ion particle flow generating device 10 from the air inlet 120 is filtered through the front and rear granular activated carbon, the aldehyde-reactive composite mesh, the photocatalyst and the multi-catalyst, and then irradiated by ultraviolet rays to achieve filtration sterilization.

Two filter systems 140 are respectively disposed on the front and rear sides of the high-energy negative oxygen ion particle flow generating device 10. The first filter layer 140a is substantially rectangular and covers the elongated opening of the air inlet 120 to allow all the gas entering the air inlet 120 to enter. Passing through the first filter layer 140a.

The outer casing 12 is provided with a substantially rectangular first intermediate partition 12c and a second intermediate partition 12d. The first intermediate partition 12c is parallel to the front side panel 125 and adjacent to the front side panel 125, and the second intermediate partition 12d is parallel to The rear side panel 127 is adjacent to the rear side panel 127. Wherein, the filter system 140 is located on the front side of the high-energy negative oxygen ion particle flow generating device 10, the first filter layer 140a is disposed between the front side plate 125 and the first intermediate partition plate 12c, and the first filter layer 140a is received in the first A rectangular receiving groove 12e is formed in the middle partition plate 12c, and the first intermediate partition plate 12c is formed with a second filter layer 140b having a circular grid shape facing the fan 142a. Similarly, in the filter system 140 on the rear side of the high-energy negative oxygen ion particle flow generating device 10, the first filter layer 140a is disposed between the rear side plate 127 and the second intermediate partition 12d and the first filter layer 140a is received in the first A rectangular receiving groove 12f is formed in the second middle partition 12d. The second middle partition 12d is formed with a second filter layer 140b having a circular grid shape at the fan 142a, and the front side of the second middle partition 12d is fixed. The third filter layer 140c is disposed, and the third filter layer 140c is an ultraviolet lamp tube. The second filter layer 140b located on the front and rear sides of the high-energy negative oxygen ion particle flow generating device 10 is exposed to ultraviolet light to be under the action of ultraviolet rays. Catalytic degradation of organic harmful gases and sterilization.

Of course, the filtration system 140 is not limited to the embodiment, and in other embodiments, a filtration system of other structures or materials may be employed as needed. For example, the filter layer may be added or removed as needed. For example, the first filter layer 140a may adopt other structures or materials that can remove formaldehyde, and the second filter layer 140b and the third filter layer 140c may adopt other Structure, material or technology.

Referring to Figure 5, the air supply system 142 includes a fan 142a and a duct 142c. The fan 142a is used to rotate the air in the casing 12 to flow along the air passage 142c to the air outlet 122.

In the present embodiment, the fan 142a is a centrifugal fan. The air duct 142c is substantially in an inverted R shape, and includes a housing portion 142d in which the fan 142a is housed, an air guiding portion 142e that communicates with the housing portion 142d and is located above the housing portion 142d, and communicates with the air guiding portion 142e and faces the first air outlet. The air supply window 142f of 122a is formed with a first fixing plate 142g below the air blowing window 142f. The first fixing plate 142g is located on the front side of the air duct 142c, and the second fixing plate 142h is formed above the air blowing window 142f. The fixing plate 142h is located on the top surface of the air passage 142c, and the air receiving port 142i is formed on the top surface of the air passage 142c.

In this embodiment, corresponding to the shape and structure of the air outlet 122, the number of the emitters 16 is two, one of which is fixed to the first fixing plate 142g and the transmitting pin 160b faces away from the first air outlet 122a, and the other is fixed to the second. The fixing plate 142g is fixed and the transmitting pin 160b is directed to the second air outlet 122b.

The air duct 142c is designed and constructed according to the fluid mechanics principle, and the air guiding portion 142e has a diverging structure from the fan 142a toward the air outlet 122, which can achieve the effects of small wind resistance, low noise, and large flow.

In this manner, the fan 142a drives the air to flow along the air guiding portion 142e to the air outlet 122. The air is first ionized by the emitter 16 located at the first fixing plate 142g to form negative oxygen ions, and the negative oxygen ions enter the external environment from the first air outlet 122a. Part of the air passes from the air supply port 142i to the transmitting pin 160b at the second fixed plate 142g and is ionized to form negative oxygen ions, and the negative oxygen ions are discharged from the second air outlet 122b.

Referring to FIGS. 6-9, the emitter 16 includes a firing pin assembly 160, a conductive metal sheet 162, and a high insulation load bearing strip 164. The firing needle assembly 160 includes a needle holder 160a and an array of firing pins 160b mounted to the needle holder 160a. Two high-insulation load-bearing mounting strips 164 are arranged in parallel. The two conductive metal sheets 162 are respectively fixed to the two high-insulation load-bearing mounting strips 164 by screws. The conductive metal strips 162 have four connection points for selection as the driving circuit 18 . Connection. Four firing pin assemblies 160 are connected side by side between the two conductive metal sheets 162 to allow all of the transmitting pins 160b to communicate with each other.

In the present embodiment, the emitter 16 is emitted in a planar array, and the negative oxygen ion emission is no longer a point but a surface, so that the number of shots is increased and it is easy to diffuse into the effective space. The needle holder 160a includes three needle bars arranged side by side, each needle bar is provided with 8 pin holes, one needle frame 160a is equipped with 24 firing pins 160b, and four needle frames 160a are arranged side by side to form 96 needles. The area array emitter 16 of the firing pin 160b. The needle holder 160a may be a PCB board, which is usually made of a double panel to ensure soldering reliability.

Thus, in combination with the negative high voltage drive, the emitter 16 can emit a high energy, high concentration stream of negative oxygen ions. Due to the unipolar multiple emission point (96 points in the example) emission, the so-called unipolar multi-wire emission, the oxygen obtains the least electrons and thus forms the light ions, that is, the negative oxygen ions with smaller particle size can be obtained. Claim The flow of negative oxygen ions with high energy, high concentration, small particle size and low pollution becomes a reality.

Of course, the array of emitters 16 is not limited to the rectangular array described above, but may be other more regular geometries. In addition to this, the transmitter 16 is not limited to a single pole multi-wire transmitter, but may also be a bipolar multi-wire transmitter. The unipolar multi-wire emitter is connected to the negative high voltage through a plurality of transmitting pins 160b to form a corona discharge. At this time, the discharge form is the earth and the earth as the positive electrode, so the negative oxygen ion particle flow is radiated to the earth through the discharge space. The bipolar multifilament emitter uses two sets of firing pins 160b, one connected to a negative high voltage to perform a corona discharge, and the other set parallel to the first set of firing pins 160b, which is characterized by constraining the negative oxygen ion particle flow to two The sets are fired between the pins 160b to concentrate them.

According to the charge skin effect and the principle of maximum curvature, the needle 160c of the firing pin 160b is a positive cone of a smaller cone angle to form a sharp discharge tip. Thus, due to the use of the cone-shaped emitting pin 160b, the negative oxygen ions are formed in an orderly manner, and each of the emission points on the array has a certain spacing, so that the oxygen in a large area and the free electrons of each emission point are balanced to form a negative oxygen ion, thereby effectively reducing ozone. Formation. The firing pin 160b is a gold-plated stainless steel material that is machined. The height of the needle handle 160d of the firing pin 160b is 2.5 mm. The ratio of the length L of the needle 160c of the firing pin 160b to the maximum diameter D of the needle 160c of the firing pin 160b is controlled within 15. The firing pin 160b exposes only the tip of 3 to 5 mm. The manufacturing process of the firing pin 160b is: material selection→machining molding→polishing→screening→gold plating→packaging storage for use. After the gold plating of the firing pin 160b, the welding is good, no rust and ablation, good good-end corona discharge, long life, excellent and long-lasting emission effect, and can maintain a unipolar coefficient of 0.001.

The conductive metal piece 162 is formed by a 0.5 mm thick stainless steel strip or a brass strip and is surface-polished. The high-insulation load-bearing mounting strip 164 is injection molded, and the material of the high-insulation load-bearing mounting strip 164 is made of a material having high insulation such as plexiglass or PBT.

The method of manufacturing the transmitter 16 includes the following steps:

Step 1: The needle holder 160a and the plurality of firing pins 160b are assembled into an emitting needle assembly 160. Wherein, each of the transmitting pins 160b is perpendicular to the plane of the needle holder 160a, and each of the transmitting pins 160b is parallel to each other. The firing pin assembly 160 can be mounted to the needle holder 160a by tooling or automatic welding.

Step 2: The firing needle assembly 160 is injection molded. Wherein, the firing pin assembly 160 is formed by injection molding, and only the firing pin 160b is exposed to the tip of 3 to 5 mm, and all other parts are covered by the glue. The injection molding material can be ABS.

Step 3: The plurality of firing pin assemblies 160 are assembled in an array between the two conductive metal sheets 162. Wherein, the conductive metal piece 162 is soldered to the upper wire terminal, and the conductive metal piece 162 is placed on the high-insulation load-bearing mounting strip 164 according to the required outgoing direction, and the transmitting needle assembly 160, the conductive metal piece 162 and the high-insulation bearing are screwed. The mounting bar 164 is attached and fixed. The firing pin assembly 160 is all assembled and fixed to form an area array emitter 16.

Step 4: Detect whether each of the transmitting pins is electrically connected to each other.

Step 5: The bare portion of the conductive metal piece 162 that is not covered between the respective firing pin assemblies 160 is sealed with epoxy resin.

The drive circuit 18 includes a cosine carrier generator 180, a negative high voltage accelerating electric field generator 182 coupled to the cosine carrier generator 180, and a transmitter 16 coupled to the negative high voltage accelerating electric field generator 182. The cosine carrier generator 180 is used to generate a cosine wave of a certain fluctuating frequency. The negative high voltage accelerating electric field generator 182 is used to generate a negative high voltage accelerating electric field of high energy and having a cosine variation law. The emitter 16 is used for corona discharge to form a stream of high energy negative oxygen ion particles having a cosine variation law.

The negative high voltage accelerating electric field generator 182 is mainly composed of electronic circuits such as cosine waveform generation, shaping, power amplification, high voltage generation, control protection, etc., and can be controlled, operated, displayed, remotely controlled, etc. by using a single chip microcomputer. The main function is to provide a negative high-voltage cosine pulsation accelerating electric field for the acceleration of the negative oxygen ion particle flow, and obtain a high-energy negative oxygen ion particle flow with a cosine distribution, so that the negative oxygen ion particle flow has the characteristics of time medical characteristics.

The protection circuit 20 is used to provide necessary overcurrent, overvoltage and overpower protection for each circuit device.

The control circuit 22 controls the human-machine interface interaction, the ultraviolet lamp, the fan 142a rotation speed, the drive circuit 18, and the like through the MCU.

The method for producing a high energy negative oxygen ion particle stream of the present invention comprises the following steps:

Filtering and sterilizing air to obtain clean air; and

The clean air is ionized under a negative high voltage acceleration electric field to obtain a high energy negative oxygen ion particle stream. Among them, the negative high-voltage acceleration electric field changes according to the cosine motion law so that the negative oxygen ions radiated into the space are distributed according to the cosine law.

The first air outlet 122a is formed on the front side of the outer casing 12. The second air outlet 122b is formed on the top surface of the outer casing 12. The emitter 16 is provided at both the first air outlet 122a and the second air outlet 122b. As such, the use of two emitters 16 increases the amount of negative oxygen ions, thereby increasing the concentration of negative oxygen ions in a given space. It can realize the discharge of negative oxygen ions in multiple directions, and the air purification effect is better.

Air enters the outer casing 12 from the air inlet 120, and the air entering the outer casing 12 passes through the air handler 14 to remove bacterial viruses and organic harmful gases in the air, so that finally enters the corona region of the emitter 16 to generate high energy negative. The air flowing through the oxygen ion particles is relatively clean. The high-energy negative oxygen ion particle stream generated by the emitter 16 exits the high-energy negative oxygen ion particle stream generating device 10 from the first air outlet 122a and the second air outlet 122b to enter the external space. Among them, the air handler 14 has a blowing function to push the air in the outer casing 12 to flow.

The high-energy negative oxygen ion particle flow generation device 10 of the embodiment of the present invention has high negative oxygen ion energy, high concentration, few by-products, and good quality, and can meet the requirements of medical negative oxygen ions. The high-energy negative oxygen ion particle stream has both physical particle and volatility, and can be used for treating various diseases and rehabilitation, and is beneficial to health and longevity. At the same time, the high-energy negative oxygen ion particle stream can be effectively used for air purification and indoor air treatment, and can also remove fine particles below PM2.5.

The high-energy negative oxygen ion particle flow device 10 of the embodiment of the present invention is based on the quantum balance adjustment theory of negative oxygen ions to the human body, the negative ion body field adjustment theory and the negative ion quantum resonance theory; the ion-based air negative oxygen ion is used to charge the cells. , nerve adjustment mechanism, body fluid adjustment function, participate in intracellular bioelectrical adjustment, increase Strong cell energy metabolism, elimination of reactive oxygen species, free radicals, participation in cellular gene activation and autonomic repair, increased intracellular oxygen supply, accelerated cell repair function and regeneration ability; also based on time-medical physiological life cycle theory (physical cycle, The intellectual cycle, the physiological cycle) and the cosine law of life processes and activities, as well as the life activities must be in harmony with the surrounding natural environment, and maintain the theory of harmony between man and nature in harmony with the laws of nature.

The high-energy negative oxygen ion particle flow generating device 10 of the embodiment of the present invention can generate negative oxygen ions having high energy, high concentration, small particle size, and low pollution. Among them, the high energy is obtained by accelerating the electric field to accelerate the negative oxygen ions. The high concentration is the use of an array emitter 16 to substantially increase the amount of negative oxygen ion emission (commonly known as negative oxygen ion production), resulting in a higher negative oxygen ion concentration in the space of use. The small particle size is a monopolar multifilament emitter that uses oxygen to obtain as little electron as possible and a high-speed ordered emission to form a small particle size negative oxygen ion. The term "non-polluting" means that the high-energy negative oxygen ion particle flow generating device 10 generates a flow of negative oxygen ion particles without accompanying generation of X-rays, and has a minimum ozone concentration in accordance with the standard, and a high-energy negative oxygen ion particle flow is generated. The device 10 uses photocatalyst technology, multi-catalyst technology, and ultraviolet technology to decompose organic harmful gases in the air, such as formaldehyde and benzene, and kill the bacterial virus before generating the flow of negative oxygen ions. At the same time, the negative oxygen species flow obtains an accelerating high-voltage electric field with cosine variation, which is a constant-flow pulsating electric field. The frequency of the other chord components is generally controlled below 20 kHz, and there is no disadvantage of high-frequency electromagnetic radiation pollution.

The negative oxygen ion particle energy generated by the high energy negative oxygen ion particle flow generating device 10 of the present invention is tens of times higher (usually within 100 to 200 electron volts) than the natural air negative oxygen ion. The concentration of negative oxygen ions in the flow of negative oxygen species is tens of thousands times higher than that of natural air negative ions. For medical purposes, the concentration will be higher than 5 × 10 ⁶ ions / cm ³ or more; practically recommended for medical purposes, the negative ion concentration 30 cm in front of the negative oxygen ion particle flow outlet of the high energy negative oxygen ion particle flow generating device 10 The maximum value is higher than 2 × 10 ⁷ ions/cm ³ . This is why the high-energy negative oxygen ion particle flow can achieve the aforementioned practical functions and the natural negative ions cannot achieve the above functions.

The high-energy negative oxygen ion particle flow generated by the present invention has a different form of motion of the object particles than the natural air negative ions. The air anion in nature is usually a chaotic thermal motion, known as Brownian motion. The high-energy negative oxygen ion in the high-energy negative oxygen particle flow of the present invention is linearly radiated in the initial direction along the direction of the electric field force due to the high-energy acceleration, until the propagation distance increases the energy consumption, and gradually dissolves into the air when it is gradually removed from the acceleration electric field. Brown movement until it disappears. Therefore, its diffusion migration distance is far. Effective life time is longer and the action time is longer.

The high-energy negative oxygen ion particle flow according to the present invention is based on time medicine, and the high-energy negative oxygen ion particle flow radiating has a cosine (or sine, wherein the sine and cosine are equivalent, and the phase difference is 90 degrees). Accelerating the electric field control method to distribute the negative oxygen ions radiated into the space according to the cosine law. That is to say, the high-energy negative oxygen ion particle flow for medical purposes has a high-energy negative oxygen ion radiating from space to the near and far distribution which is non-uniform and varies according to the cosine function, and its propagation is a cosine wave. Its fluctuating frequency is an integer multiple of the frequency of human basic life activities to facilitate the absorption of human body resonance. Plus the negative ions have the same free electrons as all matter, and the resonance Sex and spin are the same. This is the root cause of the human body's absorption of negative ions, correcting genes in life, improving the body's self-immunity, and treating all diseases with all diseases.

The negative oxygen ion particle stream of the present invention achieves high energy and accelerated negative high voltage with cosine variation, controlled within a range of 25,000 volts. For medical purposes, it is recommended to use 1.5-2 million volts. It has been proved by practice that such a negative oxygen flow is suitable for human health care. Above 25,000 volts or more, the high-energy electron impact collides with the outer shell, hard objects, and obstacles of the high-energy negative oxygen ion particle flow generating device 10, which may cause the inner layer electronic transition emission, which may be accompanied by X-rays. Accelerated voltage below 0.6 million volts, its energy for air purification and health care can also have some effects, but can not achieve health care and disease treatment.

The high-energy negative oxygen species flow of the invention has a small particle size and high energy, and is more easily absorbed into the human body than the natural air negative oxygen ions existing in the natural world. The natural negative oxygen ions are usually small in energy, usually In a few to one or twenty electron volts, the main absorption method of the human body is to inhale negative oxygen ions from the nose and mouth through breathing. It is almost impossible to directly enter the blood vessels and cells from the human skin. In the present invention, the high-energy negative oxygen ion particle flow has a negative oxygen ion particle diameter of less than 2 nanometers, an energy of about 200 electron volts, a human skin pore size of 30-50 nanometers, and a blood vessel and a cell membrane pore diameter of 20 nanometers or more. The negative oxygen ion of the high-energy negative oxygen ion particle flow of the invention can not only be easily absorbed into the body through the breathing due to its small particle size and high energy, but also can directly enter the body through the human skin, and can even directly enter the blood and pass through. The cell membrane enters the cell, thereby producing a health care function that is not possible with ordinary negative oxygen ions.

The high-energy negative oxygen ion particle flow of the invention is used for air purification and indoor air treatment, mainly by releasing a large amount of high-energy negative oxygen ions into a limited space, actively capturing space particle dust, and making it like a snowball, continuously combining and aggravating The dust particles settle to the surface of the earth under the action of gravity. The reason for its active capture is that the general dust and particles are positively charged, while the negative oxygen ions are negatively charged. The lighter and finer particles such as PM2.5 and PM1 are more easily removed by the flow of negative oxygen ions. The scientific community has proved that when the concentration of negative oxygen ions reaches 2×10 ⁴ ions/cm ³ , PM2.5 is almost zero. .

The high energy negative oxygen ion particle flow generating device 10 of the embodiment of the present invention includes a transmitter 16 and a negative high voltage acceleration electric field generator 182. Transmitter 16 includes an array of firing pins 160b. A negative high voltage accelerating electric field generator 182 is coupled to the emitter 16 and a negative high voltage accelerating electric field generator 182 is provided to provide a negative high voltage voltage to the emitter 16 to cause a corona discharge at the tip of each of the firing pins 160b to form negative oxygen ions.

In the high-energy negative oxygen ion particle flow generating device 10 of the embodiment of the present invention, since the emitter 16 adopts the array type emitting pin 160b, the negative oxygen ion emission is no longer a point but a face, and the number of negative oxygen ions in a certain space. Increase to increase the concentration of negative oxygen ions. And the emitter 16 is connected to the negative high voltage acceleration electric field generator 182, and the negative oxygen ions can obtain higher energy under the acceleration electric field.

In the present embodiment, the high-energy negative oxygen ion particle flow generating device 10 includes a housing 12 in which the emitter 16 is housed. An air inlet 120 is formed on the left and right sides of the outer casing 12, a first air outlet 122a is formed on the upper side of the outer casing 12, and a second air outlet 122b is formed on the front side of the outer casing 12. Thus, the high-energy negative oxygen ion particle flow generating device 10 can achieve the front side and the top surface of the air, increase the air purification range, and increase the concentration of the negative oxygen ions.

In the present embodiment, the casing 12 houses a fan 142a and a duct 142c. The fan 142a is disposed in the duct 142c. The duct 142c is for guiding the gas sucked from the air inlet 120 to the first air outlet 122a and the second outlet. Tuyere 122b. In this manner, the gas sucked from the air inlet 120 is guided to the first air outlet 122a and the second air outlet 122b by the fan 142a and the air duct 142c.

In the present embodiment, the air duct 142c is substantially in an inverted R type, and the air duct 142c includes a housing portion 142d in which the fan 142a is housed, an air guiding portion 142e that communicates with the housing portion 142d and is located above the housing portion 142d, and the air guiding portion 142e. The air blowing window 142f that communicates with the first air outlet 122a forms a air blowing port 142i that communicates with the second air outlet 122b on the top surface of the air duct 142c. In this way, the air passage 142c is designed and constructed according to the fluid mechanics principle, and the air guiding portion 142e has a gradually expanding structure from the fan 142a toward the air outlet 122, and the effect of small wind resistance, low noise, and large flow rate can be achieved.

In the present embodiment, the front side of the air duct 142c is formed with a first fixing plate 142g located below the air blowing window 142f, and the top surface of the air channel 142c is formed with a second fixing plate 142h, and the rear side of the first fixing plate 142g is fixed. The emitter 16 having the firing pin 160b facing away from the first air outlet 122a is fixed to the second fixing plate 142g with the emitter 16 of the transmitting pin 160b directed to the second air outlet 122b. In this way, the emitter 16 can sufficiently corona discharge the gas directed to the first air outlet 122a and the second air outlet 122b to form negative oxygen ions, thereby increasing the discharge amount of the negative oxygen ions.

In the present embodiment, the filter system 140 is provided on the front and rear sides of the outer casing 12 to filter the gas sucked into the air inlet 120. Thus, the filtration system 140 can effectively filter and sterilize the air.

In the present embodiment, the negative high voltage voltage is modulated by the human physiological life type cosine wave for health rehabilitation and disease treatment. In this way, negative oxygen ions which are beneficial to the resonance absorption of the human body can be obtained.

In the present embodiment, the voltage oscillation frequency of the negative high voltage is less than 20 kHz. That is, the cosine frequency of the negative high-voltage fundamental wave is less than 20KHz, so that there is no possibility of high-frequency radiation, and electromagnetic radiation pollution does not occur.

In the present embodiment, the voltage value of the negative high voltage is between -0.6 and -25,000 volts. Preferably, in the present embodiment, when used for health rehabilitation and disease treatment, the voltage value of the negative high voltage is between -1.5 and -20,000 volts. In this way, the ionized negative oxygen ions are more suitable for human health care.

A method of manufacturing a high energy negative oxygen ion particle stream according to an embodiment of the present invention includes the following steps:

Providing a transmitter 16, the transmitter 16 comprising an array of firing pins 160b;

A negative high voltage voltage is applied to the emitter 16 to corona discharge each of the firing pins 160b to form a stream of high energy negative oxygen ion particles.

In the method of fabricating a high energy negative oxygen ion particle stream of an embodiment of the present invention, each of the emitter pins 160b is corona-discharged to form a stream of high energy negative oxygen ion particles having a higher energy by applying a negative high voltage voltage to the emitter 16. launcher 16 Using the array type firing pin 160b, the negative oxygen ion emission is no longer a point but a face, and the number of negative oxygen ions in a certain space increases, thereby increasing the concentration of negative oxygen ions.

In the present embodiment, the firing pin 16 is a gold-plated stainless steel needle. Thus, after the gold plating of the firing pin 160b is performed, the welding is good, there is no rust and ablation, the good tip corona discharge is maintained, the life is long, the emission effect is excellent and long-lasting, and the unipolar coefficient of 0.001 can be maintained.

In the present embodiment, the tip end of the firing pin 160b has a regular conical shape. Thus, a sharp discharge tip is formed, and the corona discharge of the firing pin 160b produces a negative oxygen ion effect.

In the present embodiment, the length of the bare tip of the firing pin 160b is 3 mm to 5 mm. Thus, the tip of the firing pin 160b has a better corona discharge effect, reducing the possibility of ozone generation.

In the present embodiment, the voltage value of the negative high voltage is between -0.6 and -25,000 volts. Preferably, the voltage value of the negative high voltage for use in health care rehabilitation and disease treatment is between -1.5 and -20,000 volts. In this way, the ionized negative oxygen ions are more suitable for human health care.

In the present embodiment, the negative high voltage voltage is modulated by the human physiological life type cosine wave for health rehabilitation and disease treatment. In this way, it is beneficial for the human body to absorb negative oxygen ions.

In the present embodiment, the voltage oscillation frequency of the negative high voltage is less than 20 kHz. That is, the cosine frequency of the negative high-voltage fundamental wave is less than 20KHz, so that there is no possibility of high-frequency radiation, and electromagnetic radiation pollution does not occur.

In the present embodiment, the negative high voltage voltage waveform is modulated with an integer multiple of the frequency of the human physiological life cosine wave or a nearly integer multiple of the modulation signal, and the frequency of the human physiological vital cosine wave is the human body pulse frequency or heart rate. In this way, it is beneficial for the human body to absorb negative oxygen ions.

In the present embodiment, a pretreatment for filtering and sterilizing air is also included. In this way, the produced negative oxygen ions are made cleaner and healthier.

Referring to FIG. 10, the structure of the area array gold needle negative oxygen ion particle flow emitter 16 of the embodiment of the present invention includes at least one firing needle assembly 160. Each of the firing needle assemblies 160 includes a needle holder 160a and a plurality of firing pins. 160b. The needle holder 160a is for connection to the drive circuit 18. A plurality of firing pins 160b are arranged in an array on the needle holder 160a and are electrically connected to the needle holder 160a. The needle holder 160a and the firing pin 160b are covered with a first insulating layer 160e. The firing pin 160b includes a tip end portion 160f exposed from the first insulating layer 160e for corona discharge to form negative oxygen ions. The needle holder 160a includes an electrode that leaks from the first insulating layer 160e.

In the structure of the area array type gold needle negative oxygen ion particle stream emitter 16 of the embodiment of the present invention, since the plurality of emitter pins 160b are arranged in an array, the negative oxygen ion emission is no longer a point but a face, thereby emitting the quantity. Increased, easy to diffuse into the effective space, thereby increasing the concentration of negative oxygen ions.

In the present embodiment, the number of the transmitting pin assemblies 160 is multiple, and the emitter 16 further includes a conductive metal piece 162 and a high-insulation bearing mounting strip 164. The plurality of transmitting pin assemblies 160 are electrically connected by the conductive metal piece 162. Conducting gold The sub-pieces 162 are mounted on the high-insulation load-bearing mounting strips 164, respectively.

In this way, the plurality of transmitting needle assemblies 160 are connected side by side into the emitter 16, the emitting point of the emitter 16 is increased, the emitting surface is increased, the concentration of negative oxygen ions can be increased, and the structure is simple, and the installation and disassembly are convenient, and the assembly can be assembled as needed. Into the transmitter 16.

In the present embodiment, the emitter 16 further includes a second insulating layer that surrounds the exposed portion of the metal sheet 162. The second insulating layer may be an epoxy resin. But not limited to epoxy resin. In this way, the conduction of the metal piece 162 is prevented from leaking to improve safety.

In the present embodiment, the tip ends of the tip portions 160f are all in the same plane. In this way, surface array emission can be better formed to increase the concentration of negative oxygen ions.

In the present embodiment, the firing pin 160b conforms to: L/D ≤ 15, wherein L is the length of the needle 160c and D is the maximum diameter of the needle 160c. Thus, it is convenient to mount the firing pin 160b on the needle holder 160a, and the firing pin 160b can generate a negative oxygen ion by a better corona discharge.

In the present embodiment, the maximum diameter of the needle 160c is 1.2 mm, and the length of the needle 160c is 12 mm to 15 mm. Thus, the firing pin 160b can form a negative oxygen ion with a good corona discharge, and the firing pin 160b is easy to process and has less consumables.

In the present embodiment, the exposed length of the tip end portion 160f is 3 mm to 5 mm. Thus, the tip of the firing pin 160b has a better corona discharge effect, reducing the possibility of ozone generation.

In the present embodiment, the firing pin 160b is a gold-plated stainless steel needle. Thus, after the gold plating of the firing pin 160b is performed, the welding is good, there is no rust and ablation, the good tip corona discharge is maintained, the life is long, the emission effect is excellent and long-lasting, and the unipolar coefficient of 0.001 can be maintained.

In the present embodiment, the needle holder 160a is a PCB board. In this way, control of the transmitter 16 can be achieved.

The method for manufacturing an area array type gold needle negative oxygen ion particle flow emitter according to an embodiment of the present invention comprises the following steps:

Providing a plurality of firing pins 160b and a needle holder 160a;

The array of the plurality of firing pins 160b is assembled on the needle holder 160a to form the firing pin assembly 160; and

The firing pin assembly 160 is injection molded to form a first insulating wrap layer 160e. The tip end portion 160f of the firing pin 160b exposes the first insulating wrap layer 160e to form a negative oxygen ion by corona discharge, and the electrode of the pin holder 160a is exposed first. Insulating wrap layer 160e.

In the method for manufacturing an area array type gold needle negative oxygen ion particle flow emitter according to an embodiment of the present invention, an array of a plurality of emitting pins 160b is arranged and assembled on the needle frame 160a, so that the negative oxygen ion emission is no longer a point but a surface. The number of negative oxygen ions in a certain space increases, thereby increasing the concentration of negative oxygen ions.

In this embodiment, the method for fabricating an area array gold needle negative oxygen ion particle stream emitter further comprises the following steps:

Assembling a plurality of firing pin assemblies 160 on the conductive metal sheet 162; and

The conductive metal piece 162 is mounted on the high insulation load bearing strip 164.

In this way, the plurality of firing pin assemblies 160 are assembled on the conductive metal piece 162, which increases the emission point of the negative oxygen ions, enlarges the emitting surface of the negative oxygen ions, and increases the emission amount of the negative oxygen ions, thereby increasing the amount of the negative oxygen ions. The concentration of negative oxygen ions in a certain space.

In this embodiment, after the array of the firing pin assembly 160 is assembled, it is detected whether each of the transmitting pins 160b is electrically connected to each other. If it is turned on, the conductive metal piece 162 is exposed between the transmitting pin assembly 160 to be partially injection molded to form the first portion. Two insulation covers. In this way, avoid producing bad products.

In the present embodiment, the conductive metal piece 162 is soldered to the upper wire terminal, and the conductive metal piece 162 is placed on the high-insulation load-bearing mounting strip 164, and the firing pin assembly 160, the conductive metal piece 162, and the high-insulation load-bearing are mounted by screws. Strips 164 are connected and secured. Thus, the structure is simple and easy to install and disassemble.

In the present embodiment, the exposed length of the tip end portion 160f is 3 mm to 5 mm. Thus, the tip end portion 160f of the firing pin 160b has a better corona discharge effect, reducing the possibility of ozone generation.

In the present embodiment, the firing pin 160b conforms to: L/D ≤ 15, wherein L is the length of the needle 160c of the firing pin 160b, and D is the maximum diameter of the needle 160c. Thus, it is convenient to mount the firing pin 160b on the needle holder 160a, and the firing pin 160b can generate a negative oxygen ion by a better corona discharge.

In the present embodiment, the maximum diameter of the needle 160c is 1.2 mm, and the length of the needle 160c is 12 mm to 15 mm. Thus, the firing pin 160b can form a negative oxygen ion with a good corona discharge, and the firing pin 160b is easy to process and has less consumables.

In the present embodiment, the firing pin 160b is made of a stainless steel material and the outer surface is gold plated.

Thus, after the gold plating of the firing pin 160b is performed, the welding is good, there is no rust and ablation, the good tip corona discharge is maintained, the life is long, the emission effect is excellent and long-lasting, and the unipolar coefficient of 0.001 can be maintained.

In the present embodiment, each of the firing pins 160b is perpendicular to the plane of the needle holder 160a and each of the firing pins 160b is parallel to each other, and the tip of the firing pin 160b is in the same plane. In this way, it is ensured that the transmitting pins 160b are arranged in an array, and the surface array emission can be well formed, so that the negative oxygen ion emission is no longer a point but a surface, and the number of negative oxygen ions in a certain space increases, thereby increasing The concentration of large negative oxygen ions.

In the present embodiment, the needle holder 160a is a PCB board. As such, control of the transmitter 16 is achieved.

Referring to FIG. 11, a driving circuit 18 of a high-energy negative oxygen ion particle flow generator according to an embodiment of the present invention includes a cosine carrier generator 180 and a negative high-voltage accelerating electric field generator 182. A cosine carrier generator 180 is used to generate a cosine wave. A negative high voltage accelerating electric field generator 182 is coupled to the cosine carrier generator 180 for forming a negative high voltage that varies according to a cosine wave. The high energy negative oxygen ion particle stream generator 10 includes a transmitter 16, a negative high voltage accelerating electric field generator 182 and a transmitter. 16 is connected to cause the emitter 16 to corona discharge to form negative oxygen ions that vary in accordance with the law of cosine wave motion.

The drive circuit 18 of the high-energy negative oxygen ion particle flow generator of the embodiment of the present invention includes a cosine load The wave generator 180 and the negative high voltage accelerating electric field generator 182 connected to the cosine carrier generator 180 cause the emitter 16 connected to the negative high voltage accelerating electric field generator 182 to corona discharge to form negative oxygen ions which change according to the cosine wave motion law. The generated negative oxygen ions have high energy and are more conducive to human absorption.

In the present embodiment, the cosine carrier generator 180 is loaded with a human physiological life cosine wave. Thus, the negative oxygen ions ionized by the emitter 16 are more favorable for human body resonance absorption.

In the present embodiment, the fluctuation frequency of the physiological life cosine wave of the human body is an integral multiple of 60-80 times/min. Thus, the negative oxygen ions ionized by the emitter 16 are more favorable for human body resonance absorption.

In the present embodiment, the negative high voltage accelerating electric field generator 182 is coupled to the virtual ground charge balancing network 184 to use the earth as a positive electrode such that negative oxygen ions radiate from the emitting end of the emitter 16 to the earth.

Thus, the negative oxygen ions emitted by the emitter 16 can diffuse over a wide range without being concentrated in the emission region, increasing the air purification range, and the high-energy negative oxygen ion particle flow generator 10 does not exhibit an electric charge phenomenon.

In the present embodiment, the drive circuit 18 is connected to the power supply input unit 186, and the protection circuit 20 is connected between the drive circuit 18 and the power supply input unit 186 to prevent the drive circuit 18 from overcurrent and overvoltage.

Thus, the drive circuit 18 is protected by the protection circuit 10 to prevent the drive circuit 18 from overcurrent and overvoltage.

In the present embodiment, the drive circuit 18 is connected to a control circuit 22 for controlling the drive circuit 18 in accordance with user input. As such, the drive circuit 18 is controlled by the steering circuit 22.

In the present embodiment, the high-energy negative oxygen ion particle flow generator 10 is provided with a human-machine interaction interface 26, and the human-machine interaction interface 26 is connected with the manipulation circuit 22 to artificially regulate the fluctuation frequency of the human physiological life cosine wave.

In this way, the human-computer interaction interface 26 is used to artificially regulate the fluctuation frequency of the human physiological life cosine wave.

In the present embodiment, the voltage value of the negative high voltage is between -0.6 and -25,000 volts. Preferably, the voltage value of the negative high voltage for health care rehabilitation and disease treatment is between -1.5 and -20,000 volts. Thus, the negative oxygen ions ionized by the emitter 16 are more suitable for human health care.

Referring to FIG. 12 and FIG. 13 , together with FIG. 6 and FIG. 7 , an off-machine smog and soot air purifier 310 according to an embodiment of the present invention includes a main air duct 312 , a first fan 314 , a transmitter 16 , and a left guide . The flow duct 318, the right guide duct 320, the second fan 322, and the third fan 324 have an air inlet 3120 formed on the rear side of the main duct 312, and an air outlet 3122 formed on the front side of the main duct 312. The first fan 314 is disposed at the air inlet 3120. The emitter 316 is disposed at the air outlet 3122, and the emitter 16 includes an array of firing pins 160b. The tip of the firing pin 160b is corona discharge formed with negative oxygen ions. The left guiding air duct 318 and the right guiding air duct 320 are disposed on the left and right sides of the main air duct 312. The second fan 322 is disposed in the left air guiding duct 318, and the third fan 324 is disposed in the right air guiding duct 320. The left deflecting duct 318, the right guiding duct 320, the second fan 322, and the third fan 324 are used to drive the airflow to form a gas circulation.

In the off-machine elimination smog and soot air purifier 310 of the embodiment of the present invention, the arrayed emission needle 160b is used, and the negative oxygen ion generation is no longer a point but a surface, so that the number of negative oxygen ions is emitted. increase. The gas flow is caused by the left air guiding channel 318, the right air guiding channel 320, the second air fan 322, and the third fan 324 to form a gas circulation, so that the negative oxygen ions emitted by the main air channel 312 are rapidly outwardly diffused. The concentration of negative oxygen ions in various places in the limited space is rapidly increased. Because the negative oxygen ions are negatively charged, they will actively capture various smog, soot and particles in the air, so that all kinds of soot and particles will be combined and aggravated, and finally settled with the ground to remove the smog and soot particles in the limited space. Remove fine particles below PM2.5.

Specifically, when the spatial negative oxygen ion concentration reaches 20,000/cm 3 , the fine particles below PM 2.5 in the space are close to zero. The off-machine elimination smog and soot air purifier 310 of the embodiment of the present invention is provided with a left guiding air duct 318, a right guiding air duct 320, a second fan 322 and a third fan 324 on both sides of the main air duct 312. A high-speed airflow is generated on both sides of the main air duct 312 to drive a limited space of air to form a gas circulation. According to the principle of fluid mechanics, the gas pressure becomes lower in the place where the flow velocity is larger, so that the flow of negative oxygen ions emitted from the main air channel 312 is rapidly diffused outward, so that the concentration of negative oxygen ions in the limited space is rapidly increased, and the space is negatively ionized. The concentration can reach 20,000/cm 3 or more.

The off-machine elimination smog and soot air purifier 310 of the embodiment of the present invention has a negative oxygen ion concentration of 20 million/cm 3 when the air outlet 3122 of the main air passage 312 is in the left guide air duct 318 and the right guide air flow. Under the action of the channel 320, the concentration of negative oxygen ions can reach several hundred to tens of millions/cm 3 within 1-2 meters from the machine.

The limited space in the embodiment of the present invention refers to a closed or partially enclosed space that is relatively isolated from the outside, such as a bedroom, a living room, and the like.

Specifically, the external smog elimination and soot air purifier 310 is substantially rectangular parallelepiped, and the main air duct 312, the left air guiding air duct 318 and the right air guiding air duct 320 are substantially rectangular, and the left guiding air duct 318 and the right guiding duct The flow ducts 320 are respectively located on the left and right sides of the main air duct 312, and the main air ducts 312 are separated from the left air guiding ducts 318 and the right air guiding ducts 320. The upper end of the front side of the purifier 310 is provided with a liquid crystal display 332 and a control button 334.

In the present embodiment, the first fan 314 is an axial fan. In this manner, the first fan 314 uses an axial fan to supply air to the main air duct 312, so that the air continuously flows from the air inlet 3120 to the air outlet 3122 to ensure continuous air flow in one direction.

In the present embodiment, a first filtering device 326 is provided in the main air duct 312. In this manner, the air entering the main air passage 312 is filtered by the first filtering device 326, adsorbing odor, degrading organic harmful gases such as aldehydes and benzene, and killing the bacterial virus.

Specifically, the first filtering device 326 includes a primary effect, an activated carbon, an aldehyde-reducing combination filter 3260 disposed near the air inlet 3120, and an ultraviolet lamp 3262 located at the front side of the primary effect, activated carbon, and an aldehyde-removing combination filter 3260, respectively. Two nano photocatalysts 3264 disposed on the front and rear sides of the ultraviolet lamp tube 3262 and a nano multi-sensor network 3266 disposed between the nano photocatalyst 3264 and the emitter 316.

The primary effect, activated carbon, and aldehyde-reducing combination filter 3260 can perform primary filtration on the air in the main air passage 312 and eliminate Formaldehyde, adsorption of odor. Nano photocatalyst 3264 can degrade organic harmful gases such as aldehydes and benzenes under the irradiation of ultraviolet light tube 3262. Ultraviolet light uses a wavelength of 253.7 nm for killing bacterial viruses. Nano-multi-catalyst network 3266 has the function of degrading aldehydes and benzene organic harmful gases under low light and no light conditions, and decomposing and killing bacterial viruses.

In the present embodiment, the second fan 322 and the third fan 324 are cross flow fans.

In this manner, the second fan 322 and the third fan 324 use the cross flow fan to supply air to the left guiding air channel 318 and the right guiding air channel 320, so that high-speed airflow occurs on both sides of the main air channel 312, and a limited space is formed to form a gas circulation.

In the present embodiment, a left air inlet 3180 is formed on the left side of the left air guiding duct 318, and a left air outlet 3182 is formed on the front side of the left air guiding duct 318. A right air inlet 3200 is formed on the right side of the right air guiding duct 320, and a right air outlet 3202 is formed on the front side of the right air guiding duct 320.

In this way, high-speed airflow occurs on both sides of the air outlet 3122 of the main air duct 312. According to the principle of fluid mechanics, the air pressure becomes lower in the place where the flow velocity is larger, so that the flow of negative oxygen ions emitted from the main air channel 312 rapidly spreads out. Thereby, the concentration of negative oxygen ions throughout the limited space is rapidly increased.

In the present embodiment, a second filtering device 328 is disposed in the left guiding air duct 318, and the second filtering device 328 is located at the left air inlet 3182. A third filtering device 330 is disposed in the right guiding air duct 320, and the third filtering device 320 is located at the right air inlet 3200. Specifically, the second filter device 328 and the third filter device 330 employ an activated carbon primary filter. In this manner, the air entering the left and second deflecting ducts 318 and 320 is filtered by the second filtering device 318 and the third filtering device 320.

In the present embodiment, the left guiding air duct 318 and the right guiding air duct 320 are symmetric with respect to the main air duct 312, and the second fan 322 and the third fan 324 are symmetric with respect to the main air duct 312.

In this way, the gas circulation can be better formed to drive the air flow in the limited space, so that the negative oxygen ions emitted from the main air channel 312 are rapidly outwardly diffused, so that the concentration of negative oxygen ions in the limited space is rapidly increased.

Specifically, referring to FIGS. 6 and 7 , the transmitter 16 includes an emitter assembly 160 , a conductive metal sheet 162 , and a high-insulation carrier mounting strip 164 . The firing needle assembly 160 includes a needle holder 160a and an array of firing pins 160b mounted to the needle holder 160a. Two high-insulation load-bearing mounting strips 164 are arranged in parallel, and two conductive metal sheets 162 are respectively fixed to the two high-insulation load-bearing mounting strips 164 by screws, and the conductive metal sheets 162 have four connection points for selection as a driving circuit. Junction. A plurality of firing pin assemblies 160 are connected side by side between the two conductive metal sheets 162 to allow all of the transmitting pins 160b to communicate with each other.

Thus, in combination with the negative high voltage drive, the emitter 16 can emit a high energy, high concentration stream of negative oxygen ions. Due to the unipolar multi-emission point emission, the so-called unipolar multi-wire emission, oxygen obtains the least electrons and thus forms light ions, that is, obtaining negative oxygen ions with a smaller particle size, which can achieve high energy and high medical requirements. The flow of negative oxygen ions with a small concentration, small particle size, and low pollution becomes a reality.

Of course, the array of emitters 16 is not limited to the rectangular array described above, but may be other more regular geometries.

According to the charge skin effect and the principle of maximum curvature, the needle of the firing pin 160b is a positive cone of a smaller cone angle to form a sharp discharge tip. Thus, due to the use of the cone-shaped emitting pin 160b, the negative oxygen ions are formed in an orderly manner, and each of the emission points on the array has a certain spacing, so that the oxygen in a large area and the free electrons of each emission point are balanced to form a negative oxygen ion, thereby effectively reducing ozone. Formation.

The conductive metal piece 162 is formed by a 0.5 mm thick stainless steel strip or a brass strip and is surface-polished. The high-insulation load-bearing mounting strip 164 is injection molded, and the material of the high-insulation load-bearing mounting strip 164 is made of a material having high insulation such as plexiglass or PBT.

In the present embodiment, the firing pin 160b is a gold-plated stainless steel needle. The firing pin 160b is directed to the air outlet 3122. Thus, after the gold plating of the firing pin 160b is performed, the welding is good, there is no rust and ablation, the good tip corona discharge is maintained, the life is long, and the emission effect is excellent and durable.

In the present embodiment, the transmitter 16 is connected to a negative high voltage accelerating electric field generator, and the negative high voltage accelerating electric field generator is used to provide a negative high voltage voltage of the transmitter. Specifically, the negative high voltage accelerating electric field generator is mainly composed of electronic circuits such as cosine waveform generation, shaping, power amplification, high voltage generation, control protection, etc., and can be controlled by a single chip for control, operation, display, remote control, and the like. The main function is to provide a negative high-voltage cosine pulsation accelerating electric field for the acceleration of the negative oxygen ion particle flow, and obtain a high-energy negative oxygen ion particle flow with a cosine distribution, so that the negative oxygen ion particle flow has the characteristics of time medical characteristics.

In this way, the emitter 16 is connected to the negative high-voltage accelerating electric field generator, and the negative oxygen ions can obtain higher energy under the acceleration electric field to form high-energy negative oxygen ions, which are easy to diffuse in a limited space, and the life of the negative oxygen ions is prolonged. Time is extended.

In the description of the present specification, the description with reference to the terms "one embodiment", "some embodiments", "illustrative embodiment", "example", "specific example", or "some examples", etc. Particular features, structures, materials or features described in the examples are included in at least one embodiment or example of the invention. In the present specification, the schematic representation of the above terms does not necessarily mean the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in a suitable manner in any one or more embodiments or examples.

While the embodiments of the present invention have been shown and described, the embodiments of the invention may The scope of the invention is defined by the claims and their equivalents.

Claims (38)

1. A high energy negative oxygen ion particle flow generating device, comprising:

   a transmitter comprising an array of firing pins; and

   A negative high voltage accelerating electric field generator coupled to the transmitter, the negative high voltage accelerating electric field generator for providing the emitter negative high voltage voltage to cause each of the firing pin tips to corona discharge to form negative oxygen ions.
2. The high-energy negative oxygen ion particle flow generating device according to claim 1, wherein said high-energy negative oxygen ion particle flow generating means comprises a casing containing said emitter, and said left and right sides of said outer casing are formed with The tuyere has a first air outlet formed on an upper side of the outer casing, and a second air outlet is formed on a front side of the outer casing.
3. The high-energy negative oxygen ion particle flow generating device according to claim 2, wherein a fan and a duct are housed in the outer casing, and the fan is disposed in the air duct, and the air duct is used in the air duct. The gas sucked into the air inlet is directed to the first air outlet and the second air outlet.
4. The high-energy negative oxygen ion particle flow generating device according to claim 3, wherein the air passage is substantially in an inverted R type, and the air passage includes a receiving portion in which the fan is housed, and is connected to the receiving portion. And a wind guiding portion located above the receiving portion and a air blowing window communicating with the air guiding portion and the first air outlet, wherein a top surface of the air channel is formed to be connected to the second air outlet tuyere.
5. The high energy negative oxygen ion particle flow generating device according to claim 4, wherein a front side of the air duct is formed with a first fixing plate located below the air blowing window, and a top surface of the air duct is formed a second fixing plate, the rear side of the first fixing plate is fixed with the emitter facing away from the first air outlet, and the second fixing plate is fixed with the transmitting needle pointing The transmitter of the second air outlet.
6. The high-energy negative oxygen ion particle flow generating apparatus according to claim 5, wherein a filter system is provided on the front and rear sides of the outer casing to filter the gas sucked into the air inlet.
7. The high-energy negative oxygen ion particle flow generating device according to claim 1, wherein the negative high-voltage voltage is modulated with a human physiological life-type cosine wave for use in health care rehabilitation and disease treatment.
8. The high energy negative oxygen ion particle flow generating device according to claim 7, wherein the negative high voltage voltage has a voltage oscillation frequency of less than 20 kHz.
9. The high energy negative oxygen ion particle flow generating apparatus according to claim 1, wherein the negative high voltage voltage has a voltage value between -0.6 and -25,000 volts.
10. The apparatus of claim 1, wherein the voltage of the negative high voltage is between -1.5 and -20,000 volts for health care and disease treatment.
11. A method for manufacturing a high energy negative oxygen ion particle stream, comprising the steps of:

    Providing a transmitter, the transmitter comprising an array of firing pins; and

    Applying a negative high voltage to the emitter to cause each of the emitters to corona discharge to form the high energy negative oxygen Subparticle flow.
12. The method of manufacturing a high energy negative oxygen ion particle stream according to claim 11, wherein the emitting needle is a gold plated stainless steel needle.
13. The method of manufacturing a high-energy negative oxygen ion particle stream according to claim 11, wherein the tip end of the emitter needle has a regular conical shape.
14. The method of producing a high-energy negative oxygen ion particle stream according to claim 11, further comprising a pretreatment for filtering and sterilizing the air.
15. The structure of an area array type gold needle negative oxygen ion particle flow emitter is characterized by comprising:

    At least one firing needle assembly, each of the firing needle assemblies comprising:

    a needle holder for connecting to a driving circuit; and

    a plurality of firing pins arranged in an array on the needle holder and electrically connected to the needle holder;

    The needle holder and the firing pin are covered with a first insulating layer; the emitting pin includes a tip end portion exposed from the first insulating layer for corona discharge to form negative oxygen ions; the needle holder includes The electrode in which the first insulating layer leaks.
16. The structure of an area array gold needle negative oxygen ion particle stream emitter according to claim 15, wherein the number of the emitter needle assemblies is plural. The transmitter further includes a conductive metal piece and a high-insulation load-bearing mounting strip, wherein the plurality of the transmitting pin assemblies are electrically connected by the conductive metal piece, and the conductive metal pieces are respectively mounted on the high-insulation load-bearing mounting On the bar.
17. The structure of an area array gold needle negative oxygen ion particle stream emitter according to claim 16, wherein said emitter further comprises a second insulating layer covering said exposed portion of said conductive metal sheet.
18. The structure of an area array gold needle negative oxygen ion particle flow emitter according to claim 15, wherein the tip ends of the tips are all in the same plane.
19. The structure of an area array type gold needle negative oxygen ion particle flow emitter according to claim 15, wherein the emitting needle conforms to: L/D ≤ 15; wherein L is the length of the needle of the emitting needle, D is the largest diameter of the needle body.
20. The structure of an area array gold needle negative oxygen ion particle flow emitter according to claim 15, wherein the needle holder is a PCB board.
21. The invention discloses a method for manufacturing an area array type gold needle negative oxygen ion particle flow emitter, which comprises the following steps:

    Providing a plurality of firing pins and a needle holder;

    Assembling the plurality of array of emitter pins on the needle holder to form an emitter needle assembly; and

    Forming the firing pin assembly to form a first insulating wrap layer, the tip end portion of the emitting pin exposing the first insulating wrap layer to form a negative oxygen ion by corona discharge, and the electrode of the needle holder is exposed The first insulating wrap layer.
22. The method of fabricating an area array gold needle negative oxygen ion particle stream emitter according to claim 21, wherein It also includes the following steps:

    Assembling a plurality of the array of the firing pin assemblies on the conductive metal sheet; and

    The conductive metal piece is mounted on the high insulation load bearing strip.
23. The method for fabricating an area array type gold-needle negative oxygen ion current emitter according to claim 22, wherein after the array of the firing pin assembly is assembled, detecting whether each of the transmitting pins is electrically connected to each other, and if it is turned on, Then, the exposed metal sheet exposed portion of the transmitting pin assembly is injection molded to form a second insulating covering layer.
24. The method of fabricating an area array type gold-needle negative oxygen ion current emitter according to claim 22, wherein said conductive metal piece is soldered to a wire terminal, and said conductive metal piece is placed on a high-insulation load-bearing mounting strip. The firing pin assembly, the conductive metal piece, and the high-insulation carrier mounting strip are connected and fixed by screws.
25. The method of fabricating an area array gold needle negative oxygen ion current emitter according to claim 21, wherein each of said emitter pins is perpendicular to a plane of said needle holder and each of said emitter pins is parallel to each other The tip of the firing pin is in the same plane.
26. A driving circuit for a high-energy negative oxygen ion particle flow generator, comprising:

    a cosine carrier generator for generating a cosine wave;

    a negative high voltage accelerating electric field generator coupled to the cosine carrier generator for forming a negative high voltage that varies according to a cosine wave, the high energy negative oxygen ion particle flow generator including an emitter, the negative high voltage accelerating electric field generator and The emitters are coupled to cause the emitter to corona discharge to form negative oxygen ions that vary in accordance with the cosine wave motion law.
27. A driving circuit for a high energy negative oxygen ion particle flow generator according to claim 26, wherein said cosine carrier generator is loaded with a human physiological life cosine wave.
28. The driving circuit of the high-energy negative oxygen ion particle flow generator according to claim 27, wherein the fluctuation frequency of the human physiological vital cosine wave is an integral multiple of 60-80 times/min.
29. A driving circuit for a high energy negative oxygen ion particle flow generator according to claim 26, wherein said negative high voltage accelerating electric field generator is connected to a virtual ground charge balancing network to use the earth as a positive electrode to cause said negative oxygen ion Radiation is radiated from the emitting end of the transmitter to the earth.
30. The driving circuit of the high-energy negative oxygen ion particle flow generator according to claim 26, wherein the driving circuit is connected with a power input unit, and a protection circuit is connected between the driving circuit and the power input unit. The overdrive and overvoltage of the drive circuit are prevented.
31. A driving circuit for a high-energy negative oxygen ion particle flow generator according to claim 27, wherein said driving circuit is connected to a steering circuit for controlling said driving circuit in accordance with a user input.
32. The driving circuit of the high-energy negative oxygen ion particle flow generator according to claim 31, wherein the high-energy negative oxygen ion particle flow generator is provided with a human-machine interaction interface, and the human-computer interaction interface is connected with the manipulation circuit. The artificial control of the fluctuation frequency of the human physiological life cosine wave is realized.
33. An off-machine elimination smog and soot air purifier, characterized in that it comprises:

    a main air duct, an air inlet is formed on a rear side of the main air duct, and an air outlet is formed on a front side of the main air duct;

    a first fan disposed at the air inlet;

    An emitter disposed at the air outlet, the emitter comprising an array of emitting pins, the emitter tip corona discharge forming a negative oxygen ion;

    a left deflecting air duct and a right guiding air duct disposed on the left and right sides of the main air duct; and

    a second fan disposed in the left guiding air duct and a third fan disposed in the right guiding air duct;

    The left guiding air duct, the right guiding air duct, the second fan and the third fan are used to drive a gas flow to form a gas circulation.
34. The off-machine smog-eliminating and soot air purifier according to claim 33, wherein the main air duct is provided with a first filtering device.
35. The smog-eliminating and smog-purifying air purifier according to claim 33, wherein a left air inlet is formed on a left side of the left air guiding duct, and a front side of the left air guiding duct is formed Left outlet;

    A right air inlet is formed on a right side of the right air guiding duct, and a right air outlet is formed on a front side of the right air guiding air duct.
36. The smog-eliminating and smog-purifying air purifier according to claim 35, wherein a second filtering device is disposed in the left guiding air duct, and the second filtering device is located at the left air inlet ;

    A third filtering device is disposed in the right guiding air duct, and the third filtering device is located at the right air inlet.
37. The smog-eliminating and smog-purifying air purifier according to claim 33, wherein the left guiding air duct and the right guiding air duct are symmetrical with respect to the main air duct, the second fan It is symmetrical with the third fan about the main air duct.
38. The off-machine elimination smog and soot air purifier according to claim 33, wherein said transmitter is connected to a negative high voltage acceleration electric field generator, and said negative high voltage acceleration electric field generator is for providing said transmitter negative High voltage voltage.

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