DE202022002934U1 - Capacitor capable of releasing reactive oxygen species and reactive nitrogen species after being energized - Google Patents

Abstract

Capacitor (1) capable of releasing reactive oxygen species and reactive nitrogen species after being energized and consisting of a dielectric material (10), a voltage being applied to two corresponding electrode edges of the capacitor (1) and the capacitor ( 1) generates a heating temperature, wherein the capacitor (1) is pierced with a plurality of through holes (11) which are used as an air space for supplying air, the air supplying the capacitor (1) after heating and charging and recharging function of the capacitor (1), is ionized into oxygen ions and nitrogen ions, thereby generating a plasma at room temperature and atmospheric pressure and releasing the reactive oxygen species and reactive nitrogen species that are helpful for healing the human body.

Description

BACKGROUND OF THE INVENTION

Field of invention

The present invention relates to a capacitor, and more particularly to a capacitor which is perforated to form a honeycomb shape and is energized, wherein the air surrounding and flowing through the capacitor is converted into oxygen species by heating and charge-discharge Nitrogen species is ionized, creating plasma at room temperature and atmospheric pressure and releasing the reactive oxygen species and reactive nitrogen species for healing that supports body healing.

Description of the related technique

In recent years, many studies have shown that at the time a plasma is formed, the reactions of ultraviolet rays generate neutral particles, active particles, electrons and ions. These high-energy particles can convert oxygen in the atmosphere into reactive oxygen species (ROS). ROS is very important for cells and living bodies, that is, they are an ionic byproduct generated as the living body continues an aerobic metabolic process. The generation of ROS is thought to directly lead to damage to cellular structures, which is referred to as oxidative stress. These reactants disrupt the metabolic process of the biological tissues and block cell divisions, thereby achieving the treatment effects. Furthermore, research has shown that cancer cells are more easily affected by these effects than healthy cells.

Many studies are related to plasma applications in medicine, for example sterilization and cancer therapy. In 2002, Richardson's team researched topics related to plasma used in sterilization, wound healing, and cancer and tumor therapy, and the results showed that the healing effects of plasma were strongly linked to the bacterial species. In 2003, Laroussi et al. used a system called resistance barrier discharge (RBD) to generate plasma at atmospheric pressure and conducted further research, and then they found that the difference in the sterilization effect of plasma depends on the different tensile strengths produced by the surface of the cell wall of different cell species are induced in response to the electric field of the plasma. However, the surface of each type of bacteria is likely to include few or many protuberances, so the prospect of plasma applications for sterilization is optimistic if the operating condition is sufficiently adequate to achieve the effect of breaking the static electricity of the bacterial plasma. Regarding its application in cancer therapy, some recent studies (e.g. studies from George Washington University and Nagoya University) indicated that plasma at low temperatures can kill or prevent target cancer cells and have less effect on the neighboring normal cells shows. It has even been found that plasma can increase absorption of medicine molecules by cells. This ideal feature makes plasma a good adjuvant candidate for chemical compound treatments. In addition, features such as transportability, adjustable composition, minimal injury to the human body, and gaseous state for easy access to narrow penetrations make plasma a potential tool in cancer treatment.

Based on the above research results, plasma provides sterilization and healing effects, and the inventor proposes the present invention after extensive studies and practical improvements.

SUMMARY OF THE INVENTION

The primary object of the present invention is to provide a capacitor capable of releasing reactive oxygen species and reactive nitrogen species after being energized.

The primary feature of the invention is that after the capacitor is perforated to form a honeycomb shape and is energized, the air surrounding and flowing through the capacitor is converted into oxygen ions and nitrogen ions by heating and charge-discharge is ionized, generating plasma at room temperature and atmospheric pressure and releasing the reactive oxygen ions and reactive nitrogen ions for healing that support the body's healing.

BRIEF DESCRIPTION OF DRAWINGS

• 1 is a perspective view of a single capacitor according to an embodiment of the invention.
• 2 is a cross-sectional view of a single capacitor according to an embodiment of the invention.
• 3 is a side view of the embodiment of the invention consisting of multiple capacitors connected in series or parallel.
• 4 is a diagram of the electrical characteristics - i(t), V(t) and t - of the reactor of an embodiment of the invention shown on the oscillometer during actual operation.
• 5 is a geometric structural view of symmetrical and asymmetrical electrodes according to embodiments of the invention.
• 6 is an illustrative view of an example of application of the invention to wound healing.

DETAILED DESCRIPTION OF EMBODIMENTS OF THE INVENTION

As in 1 and 2 shown, a capacitor 1 consists of a dielectric material 10 comprising a highly dielectric material such as BaTio3, _HfO2 , lead zirconate titanate (PbZrxTil-xO3), PZT, strontium bismuth tantalate (SrBi2Ta2O9 or SBT) , AlN and a material derived therefrom or another highly dielectric material. The capacitor 1 is constructed with a plurality of through holes 11, the diameter of each hole 11 can be 0.5-1.5 mm, so that the holes 11 can be used as an air gap for supplying plasma gas, and a fan 2 (as in 3 shown) is intended to blow air to the condenser 1 to increase the gas flow. A voltage is applied to the two corresponding electrode edges of the capacitor 1 (may be municipal electricity at 110 V/60 Hz or AC electricity at higher voltages and frequencies).

When a voltage is applied to the two electrode edges of the capacitor 1, the dielectric material 10 of the capacitor 1 heats up and heats up and remains at a certain temperature (e.g. 200 ° C or so). The capacitor 1 effectively reduces the ionization threshold of the air molecules due to the thermal effect of heating. The tiny holes 11 of the capacitor 1 increase the strength of the electric field in the gap through the process of charging and recharging the capacitor 1, so that the air heated by the capacitor 1 is ionized into oxygen ions and nitrogen ions, producing plasma at room temperature atmospheric pressure from reactive oxygen species ( ROS) and reactive nitrogen species (RNS), which are useful for the human body, are released, and the fan continues blowing to continuously supply gas so that the plasma can be continuously generated. In addition, the capacitor 1 includes a plurality of tiny honeycomb holes 11 connected in series with the plasma flow, thereby accumulating minimal plasma current for high plasma strength, thereby increasing the density of the output plasma.

In production, as in 3 As shown, a plurality of capacitors 1 are connected in series or parallel to form a device for increasing the output amount of reactive oxygen species (ROS) and reactive nitrogen species (RNS) to be used.

The process of generating plasma by the system of the present invention can be understood by observing the changes in the applied voltage V(t), current i(t), and amount of electric charge Q(V). (The following description refers to the theoretical findings of AV Pipa and R. Brandenburg, Atoms 7010014 and Atoms 2019, 7, 14.) 4 shows the electrical characteristics - i(t), V(t) and t - of the reactor of the invention on the oscillator during actual operation. As can be seen, when the applied sinusoidal voltage V(t) is gradually increased from the turn-off point at the left end, the waveform of the current i(t) gradually increases. However, as V(t) increases toward the switch-on point, i(t) rises rapidly to a peak value. This means that the discharge is activated and plasma is generated. However, as the voltage value continues to increase, i(t) falls from the peak value. When V(t) reaches a maximum Vmax, i(t) becomes minimum instead. The switch-off point in 4 indicates the disappearance of the discharge effect and the extinction of the plasma. When V(t) again gradually decreases and changes to the other polarity, the waveform of current i(t) repeats the previous change, only with the polarity changed. When the switch-on point is reached, the current -i(t) increases to the peak value in the opposite direction and the plasma is activated again. However, when the voltage increases again to the point -Vmax, the plasma is deactivated again and now i(t) is reduced again. This happens repeatedly and the above reaction occurs cyclically. Accordingly, the reactor is repeatedly charged and discharged and the plasma is deactivated and activated cyclically.

The above electrodes can be as (a) or (b) in 5 be configured, which are symmetrical or asymmetrical geometric structures. Different positions of the electrodes cause a different distribution of the electric field and therefore influence the generation of the plasma. When a non-uniform electric field is applied to an uneven dielectric material 10, leakage inductance is generated in the dielectric material 10, resulting in an unstable and non-uniformly distributed plasma. This in 5 Example of electrode placement shown affects the amount of electrical charge induced by the dielectric material 10.

An example of the application of the present invention is wound healing, as in 6 shown.

A patient suffering from cancer must undergo surgery to place a stent in a blood vessel. After surgery, the present invention is used for wound healing. As in 6 As shown, it can be seen that the present invention can help the wound heal quickly so that the cells can receive sufficient energy and nutrition for tissue regeneration.

From the above description, it can be concluded that when the capacitor is pierced with holes into a honeycomb shape and is electrified, the holes can be used as the air gaps to supply plasma gas, and the air around the capacitor flows through the capacitor and is heated , to generate plasma at room temperature and atmospheric pressure during charging and discharging through the capacitor, and consequently reactive oxygen species and reactive nitrogen species are released to help the body heal.

Claims (7)

Capacitor (1) capable of releasing reactive oxygen species and reactive nitrogen species after being energized and consisting of a dielectric material (10), a voltage being applied to two corresponding electrode edges of the capacitor (1) and the capacitor ( 1) generates a heating temperature, wherein the capacitor (1) is pierced with a plurality of through holes (11) which are used as an air space for supplying air, the air supplying the capacitor (1) after heating and charging and recharging function of the capacitor (1), is ionized into oxygen ions and nitrogen ions, thereby generating a plasma at room temperature and atmospheric pressure and releasing the reactive oxygen species and reactive nitrogen species that are helpful for healing the human body. Capacitor (1) capable of releasing reactive oxygen species and reactive nitrogen species after being supplied with energy Claim 1 , wherein the dielectric material (10) comprises a highly dielectric material (10) such as BaTio3 or HfO ₂ or PZT or SBT or AlN or a material derived therefrom or other highly dielectric materials. Capacitor (1) capable of releasing reactive oxygen species and reactive nitrogen species after being supplied with energy Claim 1 , in preparation for which a device consists of several capacitors (1) in the form of a parallel connection. Capacitor (1) capable of releasing reactive oxygen species and reactive nitrogen species after being supplied with energy Claim 1 , wherein a fan is provided to blow to the condenser (1) to increase the gas flow. Capacitor (1) capable of releasing reactive oxygen species and reactive nitrogen species after being supplied with energy Claim 1 , with a diameter of the hole (11) being less than 1.5 mm. Capacitor (1) capable of releasing reactive oxygen species and reactive nitrogen species after being supplied with energy Claim 1 , wherein a configuration of the electrode edges includes a symmetrical or non-symmetrical geometric structure. Capacitor (1) capable of releasing reactive oxygen species and reactive nitrogen species after being supplied with energy Claim 1 , where the electrode edges can apply alternating voltages with a variety of amplitudes and frequencies.

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