KR100638051B1 - Installation for electric power saving having a removal function of static electricity - Google Patents

Abstract

The present invention discloses a power saving device having an antistatic function capable of exhibiting a power saving function and an antistatic function.

According to the present invention, one side is opened and has a predetermined shape, a coating layer for discharging its far-infrared energy to the free space in the housing by being applied to the inner wall of the housing, and fixed to the bottom of the housing to any power bus A body device including at least two absorber plates for delivering far infrared energy, and a bridge line for making an electrical connection between the absorber plate and the power busbar; And a cover device having a housing cover for sealing the opening face of the housing, and a reflecting plate installed on the inner side of the housing cover to concentrate far infrared energy to the absorber plate.

Accordingly, the present invention increases the far-infrared effect by ocher, charcoal, and salt, and induces the electrostatic storage on the power line by using the adsorption, conductivity, and storage property by far-infrared light, thereby neutralizing the static electricity accumulated on the power line. Provides the effect of preventing the induction of static electricity.

Far Infrared, Ceramics, Ocher, Charcoal, Salt, Power Saving, Antistatic, Static

Description

INSTALLATION FOR ELECTRIC POWER SAVING HAVING A REMOVAL FUNCTION OF STATIC ELECTRICITY}

1 is a configuration diagram showing a conventional power saving device.

2 is a perspective view showing an internal configuration of a power saving device having an antistatic function according to the present invention.

3A and 3B are views illustrating an absorber plate structure according to another embodiment of the present invention.

3c is a view showing a coating layer structure according to another embodiment of the present invention.

4 is a perspective view showing a housing cover structure of a power saving device having an antistatic function according to the present invention.

5 is a cross-sectional view of a power saving device having an antistatic function according to the present invention.

6 is a graph showing the experimental results of the present invention.

<Explanation of symbols for main drawings>

200: power saving device having an antistatic function 201: housing

203: Reflector 205: Housing Cover

207: coating layer 209: absorbing plate

211: fixing screw 215: fixing terminal

217: wire holder

The present invention relates to a device for reducing electrical energy, and more particularly, to a power saving device having an antistatic function that can increase the power saving and antistatic effect by maximizing the far-infrared radiating capacity in the power saving device using the far infrared.

In general, the power saving device is formed in the inner wall of the housing, as disclosed in the application No. 10-2002-0003057, the electric power saving device, to provide the far-infrared rays emitted from the ceramic layer in the resonance absorption state It consists of an inner cover plate.

That is, as shown in FIG. 1, the power saving device forms a ceramic layer 11 on the inner wall of the metal or plastic housing 10 in which the waveguide to the outside is blocked, mainly emitting a rotating electromagnetic wave based on the mica. In the inner space, the inner cover plate 20 supported by the gap retaining rod 12 of a predetermined height is placed, and a conductive plate through which the induced electromagnetic waves penetrate into the free space between the inner cover plate 20 and the bottom plate ( 30 is placed in the supporting insulating plate 31, and the conductive plate 30 is configured to connect with the power connection wire 33.

Here, the ceramic layer 11 is heated to about 100-150 degrees to activate the alternating magnetic field and the rotating electromagnetic waves as the covalent bond and the crystallization pie bond of the self is activated, and the resonance absorption occurs through the inner cover plate 20. Do it. That is, the rotating electromagnetic waves emitted from the surface of the ceramic layer 11 are reflected and absorbed by the cover ceramic layer 21 of the inner cover plate 20 in the free space, and the conversion movement of the rotating electromagnetic waves in the alternating magnetic field is continuously changed. As it occurs, the rotating electromagnetic wave acts to continuously emit kinetic energy that allows absorption and repetition.

The supporting insulating plate 31 is positioned so that the position of the conductive plate 30 is at the center of the bottom surface and the cover plate 20, thereby maximizing the amount of rotating electromagnetic waves induced and absorbed by the conductive plate 30. This rotating electromagnetic wave is guided to the conducting plate 30 in the free space as it is most activated in the free space between the inner cover plate 20 and the bottom surface. The conductive plate 30 is connected to the power terminal of the general outlet 40, and the power line 41 connected to the power terminal has its own flow of rotating electromagnetic waves, but is generated in the housing 10 of the economizer 100. Since the intensity of the rotating electromagnetic wave is relatively small, when the plug 34 connected through the conductive plate 30 and the electric wire 33 of the housing 10 is connected to the outlet 40, the rotation induced in the housing 10 is achieved. Electromagnetic waves are absorbed by the power lines on the closed circuit.

The rotating electromagnetic wave absorbed into the power line generates crystal bonds of new atoms in the conductive wire, and thus the new alternating magnetic field converts the thermal energy lost due to the existing electrical resistance in the conductive wire into the rotating electromagnetic wave and reduces it into effective electrical energy. As a result, these electromagnetic waves play a decisive role in reducing the resistance of various types within the wire. Reducing the resistance results in a decrease in the amount of current, which in turn reduces the amount of power consumed.

However, such a power saving device allows rotational electromagnetic waves emitted from the ceramic layer to be induced and absorbed into the conductive plate. However, the amount of far infrared rays emitted from the ceramic layer is not enough, so the power saving effect is not maximized, The problem of not obtaining additional functions and effects by the same far infrared rays is caused. In addition, there is a problem that the overall structure of the conductive plate including the housing does not have a maximum surface area capable of sufficiently inductively absorbing the rotating electromagnetic waves.

The present invention was created to solve the above problems, and an object of the present invention is to configure the coating layer for generating far-infrared ocher, charcoal and salt to emit high-infrared far-infrared to increase the power saving efficiency of the power saving device. The present invention provides a power saving device having an antistatic function.

Another object of the present invention is to implement the shape of the absorber plate to be used as a medium for transmitting high efficiency far infrared rays in a zigzag form, and the absorber plate is a three-wire load input of AC two wires (or DC two wires) including a ground wire The present invention provides a power saving device having an antistatic function capable of increasing power saving efficiency by increasing absorption of far-infrared rays.

Power-saving device having an antistatic function according to an aspect of the present invention for achieving the above object, the one side is opened and has a predetermined shape, and is applied to the inner wall of the housing to emit its far infrared energy to the free space in the housing A coating layer, at least two absorbing plates fixed to the bottom of the housing to transfer the far-infrared energy to any power busbar, and a bridge line for making an electrical connection between the absorber plate and the power busbar. Configured body device; And

And a cover device having a housing cover for sealing the opening face of the housing, and a reflecting plate installed on the inner side of the housing cover to concentrate the far-infrared energy to the absorber plate.

According to a preferred embodiment of the present invention, by treating the loess, charcoal and salt by mixing in a 1: 1: 1 ratio, by mixing a certain ratio of water to induce clay components of the loess by adsorbing to the inner wall of the housing The said coating layer is formed, It is characterized by the above-mentioned. Here, a certain ratio of water is a ratio which has a viscosity so that adsorption may be easy.

In addition, the coating layer is characterized in that more than 3mm, the housing is characterized in that made of any one of aluminum, copper, plastic material.

In addition, the absorber plate is zigzag bent or pressed in a flat plate structure, the absorber plate is configured for each phase of the power bus, it is connected to each bridge line extending with each phase of the power bus It features.

In addition, the reflecting plate is formed with a plurality of embossing of a predetermined radius, any one of the embossing has an up-embossing structure, the embossing close to the periphery has a down-embossing structure, characterized in that the reverse cone-shaped structure.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Figure 2 is an internal perspective view of a power saving device having an antistatic function according to the present invention, Figures 3a, 3b, 3c is a view showing another embodiment of the absorbing plate and the coating layer according to the present invention. Figure 4 shows a housing cover according to the present invention, Figure 5 is a view showing an assembling cross section of the power saving device having a static elimination function according to the present invention.

As shown, the power saving device 200 having an antistatic function is applied to the housing 201 having one side and the predetermined shape and the inner wall of the housing 201, and to a free space in the housing 201. A coating layer 207 for dissipating far infrared energy, at least two absorbing plates 209 fixedly installed on the bottom of the housing 201 for transferring the far infrared energy to an arbitrary power busbar, and the absorbing plate ( A body device 210 including a bridge line 219 for making an electrical connection with the power bus 209; And a housing cover 205 for sealing the opening surface of the housing 201 and an inner side surface of the housing cover 205, and a reflecting plate 203 for concentrating the far infrared energy to the absorbing plate 209. It is composed of a cover device 230 having a.

The coating layer 207 is applied to the inner wall of the housing 201, has a circular inner circumferential surface, the inner circumferential surface has a concave-convex structure. In addition, the central portion of the housing 201 implements a recessed shape of a circular structure, and the absorber plate 209 is mounted to the recessed central portion. Meanwhile, the coating layer 207 may be a copper panel 307 having a bent shape having a predetermined height, as shown in FIG. 3C.

The absorber plate 209 preferably has a maximum surface area for far-infrared radiation. Alternatively, at least two absorbing plates 209 may be provided, and at least one of the absorbing plates 209 may have different mounting directions to increase the effect thereof. That is, as shown in FIG. 3A, at least one or more absorbing plates of the plate-shaped absorbing plates 209 are provided in the vertical direction, and the remaining absorbing plates are installed in the horizontal direction, thereby setting the far-infrared radiation direction differently. This allows far-infrared rays of a certain direction to be radiated in various directions. Meanwhile, cylindrical copper may be used as a method for increasing the surface area of the absorber plate 209 as shown in FIG. 3B. Cylindrical copper is a means for increasing the surface area, and may be used by bending the outer peripheral surface of the cylindrical copper, if necessary.

The reflecting plate 203 has a circular structure of the same shape for sealing the recessed circular structure of the housing, and forms a plurality of embossing to increase the surface area of the reflecting plate 203, each of the embossing in close proximity to each other To form an uneven structure. That is, as shown in FIG. 4, any one of the embossings formed by the reflecting plate 203 has an upward structure, and the embossing close to the periphery thereof has a downward structure.

In addition, the reflector plate 203 forms a plurality of embossing, and the outer appearance of the reflector plate 203 has a cone shape starting from a center point, so that far infrared rays emitted from the body device 210 are absorbed by the absorber plate 209. ) To be aggregated. 5 is a cross-sectional view showing a coupling structure of the cover device 230 and the body device 210, as shown in the reflection plate 203 seals the opening surface of the body device 210 to have a predetermined curvature. One side of the housing 201 is formed with a wire holder 217 for inducing electrical connection between the power busbar and the absorber plate 209, respectively.

The loess is composed of a large amount of calcium carbonate (CaCo3), silica (SIO2), alumina (Al2O3), iron, magnesium (Mg), sodium (Na), and the like. Ocher composed of these components and various enzymes emits far infrared rays.

In addition, the char has an action of increasing anion, and the anion has a far infrared ray radiation effect and an electromagnetic shilding effect, so that it has conductivity and capacitance. Block or absorb electromagnetic waves from home appliances. Such charcoal has high conductivity of heat or electricity in addition to light weight, heat insulation, fire resistance, oxidation resistance, heat shock, low smoke resistance, and high electric conductivity has the ability to block electromagnetic waves. For example, the electromagnetic shielding effect of bamboo charcoal shows a blocking effect of 90% in the wavelength range of 10-1,000 MHz.

Such far-infrared ceramics are processed by mixing ocher, charcoal and salt in a 1: 1: 1 ratio, and then mixing a predetermined ratio of water to induce clay components of the ocher to adsorb to the inner wall of the housing 201, thereby Application layer 207 is formed. The coating layer 207 is preferably 3 mm or more, and the housing 201 may be made of aluminum or copper to increase the efficiency of far-infrared rays emitted from the coating layer 207. Do. In addition, the shape of the housing 201 may be a variety of shapes, such as square, round and oval, but the most preferred circular shape in consideration of far-infrared energy efficiency.

When the coating layer 207 is formed on the inner wall of the housing 201, two or more pairs of fixed terminals 215 are provided on the bottom of the housing 201 at predetermined intervals. The fixed terminal 215 may be made of plastic, ABS, rubber, or the like as a material having no conductivity. After the fixed terminal 215 is mounted, the absorbing plate 209 is fixedly installed between each pair of fixed terminals 215. The absorbing plate 209 is preferably made of copper, and has a structure capable of increasing the amount of absorption of far-infrared rays emitted from the coating layer 207. For example, the plate structure may be zigzag-folded or pressed to have a predetermined curvature to repeat, and may be manufactured in the form of a cooling fin, thereby providing a structure capable of maximizing the surface area.

At least two absorber plates 209 are fixed onto the fixed terminal 215 because the power buses are connected to each phase when the power bus is two-phase and three-phase. And, the mutual absorbing plate 209 is installed at a predetermined interval to prevent the risk of electrical contact. The absorbing plate 209 is fixedly installed by the fastening screw 213 onto the fixed terminal 215, and the fastening screw 213 fastened to one end of the fixed terminal 215 is inserted and fixed by the wire holder 217. Terminals (not shown) and the absorber plate 209 of the bridge line of the power bus to be fastened to each. If necessary, the fixed terminal 215 may use a 3P terminal that can facilitate the connection between the absorber plate 209 and the terminal.

In addition, in the present invention, each wire holder 217 is formed such that the bridge line 219 in contact with the absorber plate 209 is separated for each absorber plate 209. When a plurality of bridge lines 219 are close to each other through one tube in the process of connecting the bridge lines 219 and the power bus, the amount of far infrared rays provided through each bridge line 219 is canceled out, thereby saving power and This is because the antistatic effect is reduced.

On the other hand, the reflecting plate 203 is installed to the opening surface of the housing 201 by the fixing screw 211, the reflecting plate 203 has a copper plate material and the coating layer 207 to the inner wall of the reflecting plate 203 The same material as is applied. The copper plate reflects far-infrared rays emitted from the coating layer 207 applied to the inner wall of the housing 201 to free space in the housing 201 to increase the amount of far-infrared absorption of the absorber plate 209. The far-infrared radiation in the housing 201 is increased by the far-infrared ceramics applied to the inner wall of the reflecting plate 203.

The amount of far-infrared rays increases the amount of far-infrared rays reflected by the absorbing plate 209 through the reflecting plate 203. In order to increase the surface area of the reflecting plate 203, a plurality of embossings having a predetermined radius are formed. The concave-convex structure is formed at an adjacent position. In addition, the reflector plate 203 has a plurality of embossing, and any one of the embossing has an upward structure, and the embossing close to the periphery thereof has a downward structure to increase the surface area.

Meanwhile, in the present invention, the reflection plate 203 may be configured in a circle or ellipse shape to increase the amount of far infrared rays collected by the absorber plate 209. This is because when the housing 201 is rectangular and the reflecting plate 203 is formed in a circle or ellipse shape, and the reflecting plate 203 in a circle or oval shape is installed at a position opposite to the absorber plate 209, Far infrared rays radiated to the inner wall of the housing 201 are reflected out of the ellipse through the housing cover 205, so that the far infrared rays are diffusely reflected in free space, and eventually the infrared rays are absorbed through the elliptic reflection plate 203. It is because it is concentrated.

As such, when far infrared rays are concentrated on the absorbing plate 209, free electrons in the absorbing plate 209 may perform resonance absorption due to the far infrared wavelength band of 3 to 1000 μm. This is because the far infrared rays have unique vibrations and rotating electromagnetic waves depending on the structure of the molecules constituting the absorbing plate 209, the atoms and masses of the atoms, and the structural assembly method or arrangement state.

The rotation frequency is introduced into the power bus through the bridge line of the power bus through the absorber plate 209, the current (electrons) supplied to the load through the power bus is affected by the rotation electromagnetic waves. The rotating electromagnetic waves shape the rotating electromagnetic waves of the currents flowing through the power bus. That is, the current supplied to the load is usually supplied with an irregular frequency, and the irregular frequency is converted into a standardized frequency due to the supply of the rotating electromagnetic waves. Here, the frequency refers to the power supply signal of the DC power, including the frequency of the AC power, and includes the noise of the power signal.

Therefore, the far infrared ray is supplied to the power bus through the absorber plate 209 to remove noise of power supplied to the load. The noise is removed to uniformize the change in the movement of electrons supplied to the power bus, thereby blocking the electromagnetic waves generated by the rapid movement displacement of the electrons. Electromagnetic waves are electromagnetic waves, a wave phenomenon in which electricity and magnets propagate in a vacuum or material, or a kind of energy that moves through space, and since these wave phenomena are proportional to the acceleration force of electromagnetic waves, they are uniform on a power busbar by the rotating electromagnetic waves. Rotating electromagnetic waves play a role in inhibiting the electromagnetic waves generated on the mother bus.

In this way, the electromagnetic wave attenuates the static electricity generated in the electronic products, and as shown in Table 1, it shows the effect of removing static electricity when the present invention is applied to general household appliances.

Installation date Before installation (V) After installation (V) emplacement Electronics Name % Removal 04.09.06 PM10 35,000 House Samsung luxury 04.09.06 PM15 20,000 House Samsung luxury 42 04.09.10 PM10 12,000 House Samsung luxury 65 04.09.13 PM10 8,000 House Samsung luxury 77

This is to detect the static electricity emitted from Samsung luxury television in a single-family home, the antistatic effect of up to 77% after the device according to the present invention is installed.

On the other hand, as shown in Table 2;

Installation date Before installation (V) After installation (V) Type of installation Product Name % Removal 04.12.07 PM14 45,000 Injection Molding Machine Electronic parts 04.12.07 PM17 35,000 Injection Molding Machine Electronic parts 23 04.12.11 PM14 15,000 Injection Molding Machine Electronic parts 66 04.12.15 PM14 9,000 Injection Molding Machine Electronic parts 80 04.12.17 PM14 8,000 Injection Molding Machine Electronic parts 82

It is shown that up to 82% of static electricity generated in certain machinery applied in the production line is removed.

As such, the ocher, char, and salt constituting the coating layer 207 according to the present invention have not only anion effects but also far infrared radiation effects, which have adsorption, conductivity, and acceleration, which converts the state of electrical energy. Performance. Such far-infrared ceramics are continuously converted into rotating electromagnetic waves by an alternating magnetic field effect, causing a potential difference between the far-infrared radiator and the power bus, and the relatively extra rotating electromagnetic waves are absorbed by the power bus. As a result, generation of harmful electromagnetic waves on the power bus is reduced.

In addition, the rotating electromagnetic wave is a source of current flow of the power line, and the rotating electromagnetic wave reduces the resistance component of the power bus to provide a smooth flow of electrons to provide a power saving effect, and based on the electromagnetic wave blocking effect of the far infrared ceramics. It is possible to eliminate the electrostatic phenomenon which is the accumulation phenomenon of. This is done by neutralizing the static electricity accumulated in the power line by the anion effect and adsorption of char and salt constituting the far infrared ceramics.

In other words, static electricity is generated from electrically neutral objects because they have the same positive and negative charges, and when these two objects come into contact with or separate from each other, charges are generated at the interface, respectively. The same amount of excess positive charge and excess negative charge, i.e. static electricity, is generated because it neutralizes the excess negative charge accumulated on the power line from the negative ion effect of the far infrared ceramics. In addition, through the combination of capacitance and inductance induced on each power bus, the power factor of the system is compensated to change into a high power factor system to prevent unnecessary power waste.

6 is experimental data graphed to visually show the power saving effect in the field through the power saving device according to the present invention.

The graph shown at the top of each experimental data is data before the power saving device is installed according to the present invention, and the graph shown at the bottom of each experimental data is data when the power saving device according to the present invention is installed. As shown, the amount of power consumed in any power device is reduced by an average of 19.5%, the reactive power is 11.2%, and the R-phase current is reduced by 22.3%.

On the other hand, the power saving device having an antistatic function according to the present invention is preferably connected to each load of the system in order to remove the static electricity generated from a predetermined mechanism, and may be individually connected to each load terminal and the main distribution panel of the system as needed. will be.

As described above, the power saving device having an antistatic function according to the present invention is to apply the far-infrared ceramics mixed with ocher, charcoal, salt in a predetermined ratio to the inner wall of the predetermined shape, and to receive the far infrared rays into the free space inside the housing. By forming an absorbing plate for connecting the absorbing plate with the bridge line extending from the power bus, by supplying the rotating electromagnetic wave to the power bus based on the far infrared rays received by the absorbing plate, by the resonance action of the rotating electromagnetic wave By reducing the resistivity of the bus bar, it has the effect of maximizing power efficiency.

In addition, the power-saving device having an antistatic function according to the present invention increases the far-infrared effect by ocher, charcoal and salt, and induces the electrical storage of electric power on the power line by using the adsorption, conductivity and power storage by the far-infrared rays. It neutralizes the static electricity accumulated in the system and provides the effect of preventing static electricity in the system.

While the invention has been shown and described with respect to specific preferred embodiments thereof, the invention is not limited to the embodiments described above, and is commonly used in the art to which the invention pertains without departing from the spirit of the invention as claimed in the claims. Anyone with knowledge will be able to make various variations.

Claims (8)

A housing 201 having one side opening and having a predetermined shape, coated with an inner wall of the housing 201, an application layer 207 for dissipating its far infrared energy into a free space in the housing 201, and the housing The absorber plate 209 fixedly installed at the bottom of the 201 to transfer the far-infrared energy to an arbitrary power busbar, and the bridge line 219 for making an electrical connection between the absorber board 209 and the power busbar. Body device 210 configured to include; And A housing cover 205 for sealing the opening face of the housing 201 and an inner side surface of the housing cover 205 and a reflecting plate 203 for concentrating the far infrared energy to the absorber plate 209. Power saving device having an antistatic function, characterized in that consisting of a cover device 230 having. The power saving device having an antistatic function according to claim 1, wherein the coating layer (207) is formed by mixing ocher, char, and salt in a ratio of 1: 1: 1. The antistatic function according to claim 1 or 2, wherein the coating layer 207 has a circular recessed shape toward the center of the housing 201, and the circular inner circumferential surface has an uneven structure for increasing the surface area. Power saving device having. The method of claim 1, wherein the housing 201, The energy-saving device having an antistatic function, characterized in that the surface is made of a concave-convex structure, and the panel 307 of copper material having a circular shape. The power saving device according to claim 1, wherein the reflecting plate (203) forms a plurality of embossings to increase the surface area. The power saving device having an antistatic function according to claim 1, wherein the absorbing plate (209) is pressed in such a manner that the flat plate structure is zigzag-folded or repeatedly curved. The power saving device according to claim 1, wherein the absorbing plate (209) has a cylindrical structure made of copper. The power saving device according to claim 1, wherein the power saving device is connected to each load of the system, or connected to each main distribution panel and each load of the system.

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