KR20040028817A - Minus ions generator - Google Patents

Abstract

PURPOSE: A anion generator is provided to improve the performance of the anion generator and to generate a greater amount of anions to a defined space, compared with other anion generators. CONSTITUTION: The anion generator applies a direct current, high voltage between the cathode and the anode in order to generate cation and anion. The neutralization of cations at the cathode is much stronger than the neutralization of anions at the anode so that more anions are generated. The electrodes of the anion generator are either wire type electrodes or needle-shaped electrodes. The surface area of the cathode is larger than the surface area of the anode. Preferably, the cathode has a cylindrical shape and the anode has a wire shape to increase the electrodes' contact area so that a greater amount of anions are generated.

Description

Anion generator {Minus ions generator}

The present invention relates to an anion generating device and an anion generating method, and more particularly to a mechanism for generating new anion different from the conventional anion generating mechanism.

Conventional negative ion generating device is a device for generating negative ions using a corona discharge. In the case of generating ions using corona discharge, there are a DC corona discharge type for applying a DC high voltage between electrodes and an AC corona discharge type for applying a high voltage between electrodes, but conventionally, a DC corona discharge type has been used to generate negative ions.

While the direct current corona discharge type negative ion generator uses a needle-shaped electrode as a cathode in which corona discharge is generated, the anode is larger in size than the corona discharge electrode, and its shape is known to be flat or rice-shaped. As a direct current high voltage is applied to the anode, electrons are collected from the cathode to anionize gas molecules and fine particles.

Conventional anion generators use a method of directly transferring electrons that all of the generated negative ions can be attracted to the anode, and most of the more electrically neutralized negative ions are lost. As a result, even though a product that could be named as an anion generating device is commercially available, it is not practical to generate only anion inside the device or to fill a space in which the device is installed with anion.

Therefore, the negative ion generating mechanism of the corona discharge type can be used as an air cleaner regardless of whether it is a direct current type or an alternating current type, but the negative ions in the meaning of "an apparatus capable of filling the room where the device is placed with negative ions". It was not enough as a generator. In addition, ozone is generated at the same time during corona discharge. It is confirmed that ozone adversely affects the human body, and in particular, carcinogenic, teratogenic, and aging promoting effects are known. In addition, when ozone becomes above a certain concentration, it also smells bad. In addition, the needle corona discharge electrode has a problem of stability that can hurt the tip of the needle.

In addition, the simple linear corona discharge electrode has a defect that is easy to break, and this defect is considered to be a serious defect considering that the linear corona discharge electrode is expensive.

Accordingly, an object of the present invention is to provide a novel anion generating method, to provide an anion generating device using this method, and to provide an improved electrode that can be used in this device and other devices.

BRIEF DESCRIPTION OF THE DRAWINGS The schematic diagram which simplifies the implementation form of the negative ion generating apparatus of this invention, The schematic diagram which shows embodiment of the wire type electrode with a wire structure of this invention, The wire type electrode which has a structure which replaced and replaced the several wire of this invention. A schematic diagram showing an embodiment of implementation, a schematic diagram showing an embodiment of a wire-type electrode having a structure connected to a spring of the present invention.

Figure 2 is a quantitative figure showing the generation of negative ions by the embodiment of the negative ion generating device of the present invention.

According to the invention of claim 1, in the method of generating an anion, a step of generating a positive ion and an anion by applying a direct current high voltage between the negative electrode and the positive electrode, and the electrical neutralization to the negative electrode of the negative ion As it promotes, it is characterized by including a step of obtaining substantially only anions.

The invention described in claim 2 is based on a method of filling an anion into an interior space, and the step of generating a cation and an anion by applying a direct current high voltage between the cathode and the anode and the electrical neutralization in the cathode of the cation The anode is characterized by further promoting electrical neutralization, and having steps for obtaining substantially negative ions and diffusing the negative ions obtained by a fan.

The invention described in claim 3 is characterized by having a structure of a plurality of wires, placed in a wire-shaped electrode for ion generation.

The invention described in claim 4 is characterized in that a plurality of wires are provided with a composite structure in a wire-like electrode for ion generation.

The invention described in claim 5 is characterized by having a structure of a plurality of wires placed in the ion generating wire type electrode according to claim 4.

The invention as set forth in claim 6 is placed in an anion generator having a mechanism for applying a direct current high voltage between a cathode and an anode, wherein the cathode is larger than the anode.

The invention described in claim 7 is characterized by including the means capable of controlling the time interval of corona discharge by placing claim 7 in the anion generator according to claim 6.

The invention described in claim 8 is characterized in that, in the negative ion generating device according to claim 7, the means capable of controlling the electric corona discharge time interval is a series or parallel connection of a resistor and a capacitor.

The invention as set forth in claim 9 is placed in the anion generator according to claim 1, which is either 6 or 8, and the electric anode is the wire type electrode according to claim 1, which is either 3 or 5. do.

In the invention described in claim 10, either the sixth or the nineth invention is placed in the anion generating device according to claim 1, wherein the cathode is columnar, the anode is wired, and both poles are arranged along the same axis. It is characterized by being.

The invention described in claim 11 is characterized in that either of the eighth or the eleventh is placed in the anion generating device according to claim 1, and a promotion fan is provided for further stronger anion diffusion.

As mentioned above, the negative ion generating device in this embodiment has a columnar cathode and a wire anode disposed substantially on the same axis as the cathode. When a DC voltage is added between these electrodes, an electric field is generated. If this voltage is made high, a corona discharge will generate | occur | produce in a positive electrode and positive ions will generate | occur | produce. However, when a high field is applied to such an extent that no corona discharge occurs, gas (nitrogen molecules, oxygen molecules, etc.) between the electrodes is ionized by the electric field. At this time, cations and anions are generated in substantially the same amount. The generated cations are attracted to the cathode and the generated anions to the anode. Since the negative electrode is columnar and has a large surface area, the positive electrode is wired and the surface is narrow, so that the loss of cations occurs much earlier than the loss of anions. As a result, the number of anions exceeds the number of cations.

In addition, an important point of the present invention is that the cathode has a larger surface area than the anode, and the cathode does not necessarily need to be columnar, and the anode does not necessarily need to be a wire. However, the advantage of making the negative electrode the columnar and the positive electrode the wire is that since the contact space of the electrode is larger than the conventional one, the generation efficiency of negative ions is very high.

Furthermore, in this embodiment, a fan is provided in order to promote the diffusion of this anion. As a result, the anion can be more efficiently filled in the space provided in the present anion generator. In the present embodiment, even when a corona discharge occurs, the corona discharge is generated at the anode instead of the cathode. Thus, even if cations are generated, ozone generation is substantially eliminated. Even if a little remaining, it can be seen that it is significantly lower compared to the conventional corona discharge type negative ion generator.

In addition, the shape of the device is as shown in Figure 1, because the cathode is grounded and the cathode is in the grounded cathode, so there is no fear of electric shock due to contact accidents, it is preferable in terms of safety measures. Furthermore, the safety measures were further strengthened by covering the cathode around with an insulator such as acrylic.

As described above, when corona discharge occurs in the present embodiment, cations are generated. Therefore, in order to reduce the generation of cations, it is preferable that corona discharge is less likely to occur. The voltage (800V) which does not generate corona discharge without using this much is used. However, the generated cations are pulled out by the cathode regardless of whether they are generated by corona discharge or not, and therefore, even when corona discharge occurs, the function as an anion generator is not substantially impaired. In other words, the advantage of the present invention is that it applies a high voltage (800 V) such that corona discharge is substantially not generated. Alternatively, a high voltage may be applied to the extent that corona discharge can occur substantially. What is important is that the function as an anion generating device can be achieved by the above-described mechanism, so that generation of corona discharge is not a problem only in the present invention. Above all, it goes without saying that if the corona discharge occurs very frequently, the cation becomes more dominant than the anion in the configuration of the present invention, and the effect of the present invention may not be achieved. In view of the fact that more anions are obtained by the above-described mechanism, the voltage applied between the anodes is preferably higher. However, it is not desirable that corona discharge occurs frequently.

As a new improvement to meet both of these demands, the circuit can be configured to have a longer time interval from one corona discharge to the next. As an example of the simplest of such circuit configurations, a configuration is required in which capacitors and resistors are connected in series or in parallel before being connected to the anode. With such a configuration, since the voltage drop is generated between the electrodes by the RC circuit after the corona discharge occurs once, the corona discharge is stopped and the time until the next corona discharge occurs can be kept long. As a result, a circuit configuration in which no corona discharge is applied is realized. By changing the capacitance of the resistor and the capacitor, it is possible to adjust the time interval at which the voltage between the electrodes is raised and the corona discharge occurs.

Moreover, in order to improve the effectiveness of this invention, a wire type electrode was made to have the structure of multiple wires. For example, tungsten wire is used for the wire, and tungsten or other high melting point metal is used on this surface (see Fig. 1). According to such a structure, the electric field uniformity which arises between electrodes when a voltage is applied can be made rapid, and ion generation becomes more efficient. It goes without saying that such an effect can be obtained as the simple needle-shaped electrode has the structure of the wire. In addition, the wire-shaped anode can be composed of a plurality of lines instead of one wire. Conventional linear electrodes have the drawback of being easy to break. The reason for this is considered to be deterioration due to expansion and contraction due to temperature change at the time of operation or non-operation or temperature change due to other causes. In addition, the conventional linear electrode may be drooping by the temperature rise.

However, the present invention has improved this problem. For example, by using a wire having a double screw structure with two wires, it is possible to realize a wire that is harder to break due to a higher elasticity and less susceptible to temperature rise. In addition, to compensate for the above disadvantages, wired electrodes were connected with springs (see Figure 1). By such a configuration, it is possible to realize a configuration in which the wire is hardly broken and the relaxation action can be prevented. Although the above-mentioned wire electrode is a thing suitable especially for ion in this invention, the use is not limited to this invention, It can be used also for the conventional corona discharge type negative ion generating apparatus, It is not limited to what is called anion generating apparatus, It is also very suitable for the electrode of the apparatus which produces | generates ions, such as an air cleaner. In the negative ion generating device of the present invention, it is necessary to apply a DC voltage between the electrodes, but as the power supply, either an AC voltage or a DC voltage may be used. In the case of using an AC voltage, it is necessary to convert the AC voltage into a DC high voltage. The present invention is any configuration because the circuit can convert an AC voltage into a DC high voltage. As an example of the configuration of such a circuit, a cockcroft circuit is known.

As described above, the negative ion generating device of the present invention can fully function as an negative ion generating device in the sense of "an apparatus capable of filling the room in which the device is placed with negative ions". This is also illustrated by the experimental example shown in FIG. Figure 2 shows the amount of negative ions present in the air by operating a third-party product and the present invention for 20 minutes each. The graph plots the anion concentration (pieces / cm ³ ) versus distance from the anion generator. According to this experiment, it is considered that the anion device of the present invention has an anion generating capacity of 100 times that of other companies. To function effectively as an anion generating device, it is said that anion concentration of 100,000 or more per cm ³ is required at a position 1 m away from the device, and it is clear that the anion generating device of the embodiment of the present invention exceeds this standard.

Claims (11)

By applying a DC high voltage between the cathode and the anode, the step of generating a cation and an anion and further promoting the electrical neutralization of the cation's cathode more than the electrical neutralization of the anode of the anion, thereby substantially obtaining only an anion. Special anion generation method with steps By applying a DC high voltage between the cathode and the anode, the step of generating a cation and an anion and the electrical neutralization of the cation's cathode are promoted more than the electrical neutralization of the anion's anode. And a step of diffusing the obtained negative ions by a fan. A wire type electrode or needle electrode for ion generation, comprising a wire structure. An ion generating wire type electrode, characterized by having a plurality of wire structures. A wire type electrode for ion generation according to claim 4, wherein the wire type electrode for ion generation is characterized by having a structure of a plurality of wires. An anion generator having a mechanism for applying direct current high voltage between a cathode and an anode, wherein the cathode is larger than the anode. The negative ion generating apparatus of Claim 6 provided with the means which can control the corona discharge time interval, The negative ion generating apparatus characterized by the above-mentioned. An anion generator as set forth in claim 7, wherein a method capable of controlling an electric corona discharge time interval is a series or parallel connection of a resistor and a capacitor. A negative ion generating device as set forth in any one of claims 6 to 8, wherein the electric positive electrode is a wire type electrode as set forth in any one of Claims 8 to 5. The negative ion generating device according to any one of claims 6 to 9, wherein the negative electrode is columnar, the positive electrode is wire, and the positive electrode is arranged along the axis. The negative ion generating device according to any one of claims 6 to 11, further comprising a fan for promoting anion diffusion.