CN112652954A - Negative oxygen ion excitation device based on far infrared material and application - Google Patents

Abstract

The invention discloses a negative oxygen ion excitation device based on a far infrared material, which comprises an energy displacement body, a negative oxygen ion emission end, an induction bypass circuit and an energy control circuit, wherein the energy displacement body is arranged on the outer side of the negative oxygen ion emission end; the energy displacement body is respectively and electrically connected with the negative oxygen ion emission end and the energy control circuit through the conductive electrode; the induction bypass circuit is connected in parallel with two ends of the energy displacement body, and the induction bypass circuit is electrically connected with the energy displacement body. The negative oxygen ion excitation device can obtain high-efficiency negative oxygen ions by controlling the excitation energy of the negative oxygen ions. The voltage of the excitation circuit is isolated from the excitation end through the energy displacement body with the far infrared characteristic, so that the negative oxygen ions are generated, the production of byproducts is greatly inhibited, the generated negative oxygen ions have higher energy and a farther dissipation effect, and the negative oxygen ions can act on a larger indoor space.

Description

Negative oxygen ion excitation device based on far infrared material and application

Technical Field

The invention relates to the technical field of negative oxygen ion generators, in particular to a negative oxygen ion excitation device based on a far infrared material and application thereof.

Background

With the rapid development of health industry, people have higher and higher requirements for air quality, and need safe and nontoxic breathing air and air beneficial to human health. Among them, negative oxygen ions are called vitamins in the air, and their promotion effects on human health are widely recognized at home and abroad.

In order to improve air quality, a common instrument is a negative ion generator which is used as an electrical product indoors, the negative oxygen ion generator has certain advantages compared with other material products, but the action principle of the existing negative oxygen ion generator on the market is still in an extremely early state, namely, a sufficiently high voltage is applied to an emission end to enable the emission end to produce corona discharge, so that negative oxygen ions are generated. The method can generate negative oxygen ions with high concentration under high enough voltage, but can also generate a large amount of byproducts harmful to human bodies, such as ozone, positive ions and the like, and the energy of the generated negative oxygen ions is often insufficient, so that the effective action area of the negative oxygen ion generating device is very small, and a user cannot obtain good effect or even is harmful when using the negative oxygen ion generating device. On the other hand, if a negative oxygen ion generator with a low voltage is used, the amount of negative oxygen ions generated is reduced more greatly, although the generation of harmful by-products is reduced. The existing negative oxygen ion generating device can obtain negative oxygen ions with high safety and low concentration by adopting a voltage reduction mode or obtain negative oxygen ions with high concentration regardless of safety.

The invention aims to provide a negative oxygen ion excitation device based on a far infrared material, which obtains safe and pure negative oxygen ions by controlling the energy for exciting the negative oxygen ions.

Disclosure of Invention

In order to solve the above problems, the present invention provides a negative oxygen ion excitation device based on far infrared material, the excitation device includes an energy displacement body 11, a negative oxygen ion emission end 13, an induction bypass circuit 14 and an energy control circuit 15; the energy displacement body 11 is respectively and electrically connected with the negative oxygen ion emission end 13 and the energy control circuit 15 through the conductive electrode 12; the induced bypass circuit 14 is connected in parallel to two ends of the energy displacer 11, and the induced bypass circuit 14 is electrically connected to the energy displacer 11.

As a preferable embodiment, the raw material for producing the energy exchanger 11 contains a mineral material.

As a preferred technical scheme, the negative oxygen ion emission end 13 is made of single or multiple carbon fibers or metal products.

As a preferred technical solution, the impedance value of the induced bypass circuit 14 is 10M Ω to 1000M Ω.

As a preferable technical solution, the energy control circuit 15 at least includes a power input terminal 20, a high-frequency oscillation starting circuit 19, a high-frequency transformer 18, a variable-stage voltage-multiplying circuit 16 and an energy leakage adjusting circuit 17, and the power input terminal 20, the high-frequency oscillation starting circuit 19, the high-frequency transformer 18, the variable-stage voltage-multiplying circuit 16 and the energy leakage adjusting circuit 17 are electrically connected in sequence.

Preferably, the oscillation frequency generated by the high frequency oscillation starting circuit 19 and the high frequency transformer 18 in the energy control circuit 15 is 10KZ to 60 KZ.

As a preferable technical solution, the voltage doubling circuit 16 generates a voltage doubling for the high-frequency transformer 18 of 2 to 4 times.

As a preferable technical solution, the impedance value of the bleeding adjusting circuit 17 is 10M Ω to 1000M Ω.

As a preferred technical solution, one end of the induced bypass circuit 14 is electrically connected to the negative oxygen ion emitting end 13, and the other end is electrically connected to the energy control circuit 15.

The second aspect of the present invention also provides an application of the negative oxygen ion excitation device based on the far infrared material, which can be used for releasing negative oxygen ions.

Advantageous effects

1. The negative oxygen ion excitation device can obtain high-efficiency negative oxygen ions by controlling the excitation energy of the negative oxygen ions.

2. In the present invention, the energy displacer is made of a mineral material and has a certain far infrared characteristic.

3. The voltage of the excitation circuit is isolated from the excitation end through the energy displacement body with the far infrared characteristic, so that the negative oxygen ions are generated, the production of byproducts is greatly inhibited, the generated negative oxygen ions have higher energy and a farther dissipation effect, and the negative oxygen ions can act on a larger indoor space.

4. Various matching parameters in the excitation device can be selectively adjusted within a certain range, so that product performance configuration meeting the application requirements of actual products is obtained.

5. According to the negative ion excitation device based on the far infrared material, the production of harmful byproducts when high negative oxygen ion concentration is ensured is effectively reduced through the control of excitation energy and the conversion and isolation of the far infrared material to the emission end, so that the negative ion excitation device has high safety and high efficiency.

Drawings

Fig. 1 is a structural diagram of a negative ion excitation device based on a far infrared material provided by the present invention.

Wherein:

11-an energy displacer; 12-a conductive electrode; 13-negative oxygen ion excitation end; 14-an induced bypass circuit; 15-an energy control circuit; 16-a variable stage voltage multiplier circuit; 17-an energy bleed regulation circuit; 18-a high frequency transformer; 19-a high frequency oscillation starting circuit; 20-power supply input terminal.

Detailed Description

The disclosure of the present invention may be understood more readily by reference to the following detailed description of preferred embodiments of the invention and the examples included therein. Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. In case of conflict, the present specification, including definitions, will control.

In order to solve the above problems, the present invention provides a negative oxygen ion excitation device based on far infrared material, the excitation device includes an energy displacement body 11, a negative oxygen ion emission end 13, an induction bypass circuit 14 and an energy control circuit 15; the energy displacement body 11 is respectively and electrically connected with the negative oxygen ion emission end 13 and the energy control circuit 15 through the conductive electrode 12; the induced bypass circuit 14 is connected in parallel to two ends of the energy displacer 11, and the induced bypass circuit 14 is electrically connected to the energy displacer 11.

In some preferred embodiments, the raw material for preparing the energy displacer 11 contains a mineral material.

In some preferred embodiments, the energy displacing body 11 has far infrared characteristics, and the number of the energy displacing body 11 in the negative oxygen ion excitation device is at least one.

In the present invention, the energy displacing body 11 has a certain dielectric strength, and the energy displacing body 11 can obtain different ranges of dielectric requirements by preparing different shape sizes. When the energy replacement body is combined with the energy control circuit 15 for application, the two sides of the energy replacement body 11 are respectively connected with the negative oxygen ion emission end 13 and the energy control circuit 15 in a conductive manner by adopting a certain form of conductive electrodes 12, and the conductive electrodes are used for isolating the electric field generated by the energy control circuit 15 from directly acting on air.

In some preferred embodiments, the negative oxygen ion emitting end 13 is made of single or multiple carbon fibers or metal products.

In some preferred embodiments, the impedance of the induced bypass circuit 14 is 10M Ω -1000M Ω.

In some preferred embodiments, the energy control circuit 15 at least includes a power input 20, a high-frequency oscillation starting circuit 19, a high-frequency transformer 18, a variable-stage voltage-multiplying circuit 16, and an energy leakage adjusting circuit 17, and the power input 20, the high-frequency oscillation starting circuit 19, the high-frequency transformer 18, the variable-stage voltage-multiplying circuit 16, and the energy leakage adjusting circuit 17 are sequentially electrically connected.

In the invention, the high-frequency oscillation starting circuit 19 and the high-frequency transformer 18 are combined to form self-excited oscillation with a certain frequency, and the frequency can be matched with the parameters required by the energy displacer 11 by adjusting part of device parameters in the high-frequency oscillation starting circuit 19, so that an optimized solution is obtained. And the variable-stage voltage-multiplying circuit 16 can obtain several voltage parameters suitable for the energy displacer 11 by modifying the device parameters and the stage number therein. The energy discharge adjusting circuit 17 takes a corresponding matching value according to the parameter value of the variable-stage voltage-multiplying circuit 16, so that the function of limiting the energy transmitted to the energy displacement body 11 can be achieved.

In addition, in the invention, the energy control circuit 15 generates electric pulses with certain frequency and voltage to act on the energy displacer 11 with far infrared characteristic, so that free electrons in the energy displacer are in a reasonable energy interval, and the induced bypass circuit 14 with impedance matching acts on the negative oxygen ion emission end 13 to excite pure negative oxygen ions into air.

In some preferred embodiments, the high frequency oscillation starting circuit 19 and the high frequency transformer 18 in the energy control circuit 15 can be combined to produce an oscillation frequency matched with the requirements of the device system.

In some preferred embodiments, the oscillation frequency generated by the high frequency oscillation starting circuit 19 and the high frequency transformer 18 in the energy control circuit 15 may be 10KZ to 60 KZ.

In some preferred embodiments, the variable-stage voltage-multiplying circuit 16 generates a voltage-multiplying factor of 2-4 for the high-frequency transformer 18.

In some preferred embodiments, the impedance value of the bleeding adjusting circuit 17 is 10M Ω to 1000M Ω.

In the present invention, the discharge regulating circuit 17 in the energy control circuit 15 can limit the energy supplied to the energy displacing body 11, and can discharge the redundant energy in the system during standby, thereby ensuring safety.

In some preferred embodiments, one end of the induced bypass circuit 14 is electrically connected to the negative oxygen ion emitting terminal 13, and the other end is electrically connected to the energy control circuit 15.

In some preferred embodiments, the energy control circuit 15 has a power input 20 for supplying power to the device of the invention.

The second aspect of the present invention also provides an application of the negative oxygen ion excitation device based on the far infrared material, which can be used for releasing negative oxygen ions.

Examples

The technical solution of the present invention is described in detail by the following examples, but the scope of the present invention is not limited to the examples. Unless otherwise specified, all the raw materials in the present invention are commercially available.

Example 1

Embodiment 1 provides a negative oxygen ion excitation device based on far infrared material, the excitation device includes an energy displacement body 11, a negative oxygen ion emission end 13, an induction bypass circuit 14 and an energy control circuit 15; the energy displacement body 11 is respectively and electrically connected with the negative oxygen ion emission end 13 and the energy control circuit 15 through the conductive electrode 12; the induced bypass circuit 14 is connected in parallel to two ends of the energy displacer 11, and the induced bypass circuit 14 is electrically connected to the energy displacer 11.

The raw materials for preparing the energy displacer 11 contain mineral materials, the energy displacer 11 has far infrared characteristics, and the number of the energy displacer 11 in the negative oxygen ion excitation device is one.

In the application of the present invention, the energy displacer 11 needs to bypass an induced bypass circuit 14 for inducing excitation, the specific parameters of the induced bypass circuit 14 match the impedance of the energy displacer 11, and the impedance value of the induced bypass circuit 14 may be 10M Ω to 1000M Ω.

The energy control circuit 15 at least comprises a power input end 20, a high-frequency oscillation starting circuit 19, a high-frequency transformer 18, a variable-level voltage doubling circuit 16 and an energy discharge adjusting circuit 17, wherein the power input end 20, the high-frequency oscillation starting circuit 19, the high-frequency transformer 18, the variable-level voltage doubling circuit 16 and the energy discharge adjusting circuit 17 are electrically connected in sequence.

The high-frequency oscillation starting circuit 19 and the high-frequency transformer 18 in the energy control circuit 15 can be combined to produce an oscillation frequency matched with the requirements of a device system, and the oscillation frequency generated by the high-frequency oscillation starting circuit 19 and the high-frequency transformer 18 in the energy control circuit 15 can be 10 KZ-60 KZ.

The voltage doubling circuit 16 is used for generating voltage doubling for the high-frequency transformer 18 by 2-4 times.

The impedance value of the bleeder circuit 17 is 10M Ω -1000M Ω.

One end of the induced bypass circuit 14 is electrically connected with the negative oxygen ion emission end 13, and the other end is electrically connected with the energy control circuit 15.

The energy control circuit 15 is provided with a power input 20 for supplying power to the device according to the invention.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present invention are included in the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (10)

1. The negative oxygen ion excitation device based on the far infrared material is characterized by comprising an energy displacement body (11), a negative oxygen ion emission end (13), an induction bypass circuit (14) and an energy control circuit (15); the energy displacement body (11) is respectively and electrically connected with the negative oxygen ion emission end (13) and the energy control circuit (15) through the conductive electrode (12); the induction bypass circuit (14) is connected in parallel with two ends of the energy displacer (11), and the induction bypass circuit (14) is electrically connected with the energy displacer (11).

2. The negative oxygen ion excitation device based on far infrared material as claimed in claim 1, wherein the energy displacement body (11) is made of mineral material.

3. The far infrared material-based negative oxygen ion excitation device as claimed in claim 1, wherein the negative oxygen ion emitting end (13) is made of single or multiple carbon fibers or metal products.

4. The negative oxygen ion excitation device based on far infrared material as claimed in claim 1, wherein the impedance value of the induction bypass circuit (14) is 10M Ω -1000M Ω.

5. The negative oxygen ion excitation device based on far infrared material as claimed in claim 1, wherein the energy control circuit (15) comprises at least a power input terminal (20), a high frequency oscillation starting circuit (19), a high frequency transformer (18), a variable stage voltage doubling circuit (16) and an energy discharge adjusting circuit (17), and the power input terminal (20), the high frequency oscillation starting circuit (19), the high frequency transformer (18), the variable stage voltage doubling circuit (16) and the energy discharge adjusting circuit (17) are electrically connected in sequence.

6. The negative oxygen ion excitation device based on far infrared material as claimed in claim 5, wherein the oscillation frequency generated by the high frequency oscillation circuit (19) and the high frequency transformer (18) in the energy control circuit (15) is 10 kZ-60 kZ.

7. The negative oxygen ion excitation device based on far infrared material as claimed in claim 5, wherein the voltage doubling of the high frequency transformer (18) by the variable-stage voltage doubling circuit (16) is 2-4 times.

8. The negative oxygen ion excitation device based on far infrared material as claimed in claim 1, wherein the impedance value of the discharge adjustment circuit (17) is 10M Ω -1000M Ω.

9. The negative oxygen ion excitation device based on far infrared material as claimed in claim 1, wherein one end of the induction bypass circuit (14) is electrically connected with the negative oxygen ion emitting end (13), and the other end is electrically connected with the energy control circuit (15).

10. Use of the negative oxygen ion excitation device based on far infrared material according to any one of claims 1 to 9, wherein the negative oxygen ion excitation device is used to release negative oxygen ions.

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