JP2017208996A - Power saving device set - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power saving device set capable of attenuating higher harmonic waves by providing grounding plates among a plurality of power saving devices for improving the movement and flow of electrons and at the outsides thereof to contact the grounding plates to the ground by using a mixture of tourmaline mineral and permanent magnet powder.SOLUTION: A power saving device set 1000 comprises: a case 200; a plurality of power saving devices 100 disposed so as to be stacked in a state that mutual device outer surfaces are contacted with each other inside the case 200 for improving the movement and flow of electrons; grounding plates 500 installed among the plurality of power saving devices 100 stacked inside the case 200 and on the outermost surfaces of the outermost power saving devices 100 positioned at the outermost sides, and electrically connected to a grounding cable G; and insulating plates 300 disposed between the grounding plates 500 installed on the outermost surfaces of the outermost power saving devices 100 and the case 200 for electrically insulating them.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a power-saving device set, and more particularly, between a plurality of power-saving devices that improve the movement and flow of electrons using a mixture of tourmaline minerals and permanent magnet powders. The present invention relates to a power-saving device set that is provided with a ground plate on the outer surface and can attenuate (reduce) harmonics by grounding the ground plate.

  Recently, various studies have been actively conducted to develop alternative energy resources to replace coal and oil due to environmental pollution and lack of energy resources. For example, various studies have been made to develop and effectively use energy resources using nuclear power, wind power, tidal power, sunlight, or the like.

  However, although heat energy generated from coal, oil, or nuclear power can be used directly, most of the heat energy is generally converted into electric energy for use. In addition, it is impossible to directly use energy generated from wind power, sunlight, or tidal power, and the generated energy must be converted into electrical energy by wind power generation, solar power generation, or tidal power generation. I must.

  Therefore, it can be said that most of the energy is converted into electric energy for human use. The amount of electric energy used is increasing every year, and the supply price of electric energy tends to increase due to rising prices of fossil energy resources. Therefore, every attempt has been made socially and economically to reduce the consumption of electrical energy. In particular, development of power-saving products, improvement of power transmission processes, and development of power-saving devices that can reduce power consumption are attracting attention.

  In connection with such a power saving apparatus and method, a power saving method using far infrared rays is disclosed in Patent Document 1, which is a method of installing a ceramic mineral that radiates far infrared rays on a base shaft portion of a motor. The present invention relates to a technology for saving electricity by suppressing the generation of a resistive load due to heat generation. Patent Document 2 discloses a method for maximizing resonance absorption by supplying far-infrared rays radiated from far-infrared radiators such as sericite or gangue stone to a power line to save power. ing.

  However, all these prior arts use far infrared rays, and it is necessary to generate far infrared rays in a specific wavelength band (8 to 11 μm), and the amount of far infrared rays generated does not reach a certain level. However, the amount of generated far infrared rays is not satisfactory, and there is a problem that the power saving effect is lowered. For example, when minerals such as the above-mentioned sericite are powdered and applied to a box of a specific size, the amount of generated far infrared rays is not sufficient, and the power saving effect is not satisfactory.

  In relation to the foregoing, Patent Document 3 discloses that a rotation of a ceramic layer that has sericite as a main material on the inner wall of the power saving device and emits rotating electromagnetic waves is provided on the inner wall of the power saving device and is emitted from the ceramic layer. The power-saving device is disclosed in which an internal cover plate that exhibits a resonance absorption action by repeatedly absorbing and emitting electromagnetic waves is provided inside the device.

  Patent Document 3 adopts a method in which rotating electromagnetic waves emitted from a ceramic layer are converted into far infrared rays in free space (free space), and the far infrared rays are transmitted between the ceramic layer on the inner wall of the housing and the inner cover plate. Resonance absorption action (repetition of reflection and absorption) is generated between the ceramic layers, thereby increasing the amount of generation of rotating electromagnetic waves (that is, far infrared rays). However, even this method does not satisfy the generation amount of far infrared rays, and the power saving effect is slight, and it does not have a shockingly useful power saving effect.

  Therefore, the conventional power saving (power saving) device and method using far infrared rays have problems to be solved.

  On the other hand, since power can be defined as the product of voltage, current and power factor, it is possible to reduce power by reducing the current value by improving the current flow.

  The present applicant pays attention to the fact that when the tourmaline mineral is used, the movement and flow of electrons can be improved, and a mixture of a tourmaline mineral having a permanent electrical property and a permanent magnet powder having a permanent magnetic property is obtained. A power-saving device that can use and save power by improving the movement and flow of electrons has been developed and has already been filed and registered (Patent Document 4).

  On the other hand, in the 1970s, a problem of an electric supply system due to harmonic distortion occurred, and a harmonic filter has been developed to solve the problem. As a result, a harmonic filter using an RLC circuit has been developed, and such a harmonic filter has a problem of high heat generation and high power consumption.

JP 05-261355 A Korean Published Patent No. 2002-0028862 Korean Registered Patent No. 10-041931 Korean Registered Patent No. 10-0939757

  As described above, the present invention was created to realize a power saving device set for attenuating harmonics using a power saving device already filed by the applicant of the present application, and includes a plurality of power saving devices. It is an object of the present invention to provide a power saving device set that can effectively reduce unnecessary harmonics by configuring the power saving device set by using the above-described structure.

The power saving device set according to the embodiment of the present invention for achieving the above-described object is:
[1] A tourmaline mineral having a permanent electrical property and a permanent magnet powder having a permanent magnetic property, which are stacked in a state where the outer surfaces of the devices are in contact with each other. Installed between the plurality of power saving devices filled with the mixture and the plurality of power saving devices stacked inside the case and on the outermost surface of the outermost power saving device located on the outermost side, and grounded A grounding plate electrically connected to each of the wires, an insulating plate provided between the grounding plate and the case installed on the outermost surface of the outermost power saving device, and electrically insulating It is comprised including.

[2] The power saving apparatus set according to [1], wherein the power saving apparatus includes an apparatus housing, tourmaline powder, permanent magnet powder, and moisture (H) contained in the apparatus housing. ₂ O) a tourmaline intermediate layer which is a mixture layer, an electroconductive metal ionization plate located between the tourmaline intermediate layer inside the device casing, and a conductive material embedded in the tourmaline intermediate layer. And a board.

[3] The power-saving device set according to [2], wherein the second tourmaline intermediate layer is a mixture layer of the tourmaline powder and the water that is located inside the device housing with the tourmaline intermediate layer interposed therebetween. The ionizing plate is interposed between the tourmaline intermediate layer and the second tourmaline intermediate layer.

[4] The power saving device set according to [1], wherein the case is made of any one of plastic, stainless steel, and a stainless steel plate, and the insulating plate is made of plastic or rubber. The ground plate is formed of any one of a copper plate, an aluminum plate, and an iron plate.

[5] The power saving device set according to [1], wherein the power saving device set includes an air circuit breaker and a wiring breaker inside a power receiving panel connected to a secondary side of the transformer. It is connected to the electric power bus between the devices.

[6] In the power saving apparatus set according to [5], when the power bus is a single-phase two-wire system, two single modules of the power saving apparatus are provided on two power lines, It is characterized by being connected.

[7] The power saving device set according to [5], wherein when the power bus is a single-phase three-wire system, three single modules of the power saving device are provided on three power lines, It is characterized by being connected.

[8] The power saving device set according to [5], wherein when the power bus is a three-phase four-wire system, four single modules of the power saving device are provided on four power lines, It is characterized by being connected.

  According to the means for solving the problems described above, unnecessary harmonics can be effectively reduced by configuring the power saving device set using the power saving device and changing the structure thereof.

It is a block diagram of the power saving apparatus set which concerns on 1st embodiment of this invention. It is a disassembled perspective view which shows an example of the power saving apparatus shown in FIG. It is sectional drawing which shows an example of the power saving apparatus shown in FIG. It is a block diagram of the power saving apparatus set which concerns on 2nd embodiment of this invention. It is a block diagram of the power saving apparatus set which concerns on 3rd embodiment of this invention. It is a figure which shows the example of installation of the power saving apparatus set of this invention. It is a graph which shows a harmonic reduction efficiency to the power saving apparatus set of this invention.

  Hereinafter, the configuration and operation of embodiments of the present invention will be described with reference to the accompanying drawings. It should be noted that the same components in the drawings are denoted by the same reference numerals or symbols as much as possible even if they are displayed on other drawings.

  In the following description of the present invention, if it is determined that specific descriptions of related known techniques and configurations may unnecessarily obscure the subject matter of the present invention, the details Description may be omitted. In addition, when a specific part “includes” a specific component, unless otherwise stated, the other component is not excluded and can include the other component.

  FIG. 1 is a configuration diagram of a power saving device set 1000 according to the first embodiment of the present invention, and is a configuration diagram in the case of a three-phase four-wire system. As shown in FIG. 1, the power saving apparatus set 1000 includes a power saving apparatus 100, a case 200, an insulating plate 300, and a ground plate 500.

  The case 200 needs to be formed of a material having waterproofness and dustproofness. For example, the case 200 can be formed of a material such as plastic, stainless steel, and stainless steel plate. The plurality of power saving devices 100 disposed inside the case 200 improve the movement and flow of electrons using a mixture of a tourmaline mineral having permanent electrical characteristics and a permanent magnet powder having permanent magnetic characteristics. This is a device that realizes power saving of electric energy, and will be described in detail below with reference to FIGS. 2a and 2b.

  In these power saving apparatuses 100, as one single module, the power bus is a three-phase four-wire system, and the four power saving apparatuses 100 are stacked in four stages up and down in a state where the outer surfaces of the apparatuses are in contact with each other. The power lines R, S, T, and N are independently and electrically connected to the four power lines R, S, T, and N provided at the power supply end.

  The ground plate 500 is formed of a copper plate, an aluminum plate, an iron plate, or the like, and is disposed between the four stacked power saving devices 100 and the outermost surface of the power saving device 100 located on the outermost side. That is, it is installed on the two outermost surfaces of the uppermost stage side and the lowermost stage side of the outermost power saving apparatus 100 located at the uppermost stage and the lowermost stage, respectively, and is electrically connected to the ground line G and electrically By combining with the ground (earth), the potential difference with the power saving apparatus 100 is made to approach zero.

  The insulating plate 300 is formed by molding a material such as plastic or rubber into a plate shape, between the ground plate 500 and the case 200 installed on the outermost surface on the uppermost side of the outermost power saving device 100, and This electrically insulates between the ground plate 500 and the case 200 installed on the outermost surface on the lowermost stage side of the outermost power saving apparatus 100.

  With such a configuration of the power saving apparatus set 1000, the ground plate 500 is connected to the ground (earth), and the amount of free electrons emitted due to the potential difference of the power saving apparatus 100 is increased, and the harmonic reduction effect is increased.

  Moreover, since it plays the role which attenuates a harmonic on the characteristic of the tourmaline which comprises the power saving apparatus 100, when it connects to the ground via the ground plate 500, the harmonic which generate | occur | produces in an electric power grid | system will be in the power saving apparatus 100. Introduced harmonics reduce the electrical properties of tourmaline.

2A and 2B are an exploded perspective view and a cross-sectional view showing an embodiment of the power saving apparatus 100 shown in FIG. As shown in FIGS. 2a and 2b, an embodiment of the power saving apparatus 100 includes an apparatus casing 10, tourmaline powder filled in the apparatus casing 10, permanent magnet powder, and moisture (H ₂ O). A tourmaline intermediate layer 20 that is a mixture layer of the above, an ionization plate 30 that is located inside the apparatus housing 10 with the tourmaline intermediate layer 20 interposed therebetween, and an ionization plate 30 that sandwiches the tourmaline intermediate layer inside the apparatus housing 10. It includes a pair of second tourmaline intermediate layers 50 that are a mixture layer of tourmaline powder and moisture located outside, and a conductive plate 40 embedded in the tourmaline intermediate layer 20. Further, a plurality of block-shaped magnets 80 are embedded in the tourmaline intermediate layer 20 separately from the permanent magnet powder. Here, as shown in FIGS. 2a and 2b, in the power saving apparatus set 1000 according to the first embodiment of the present invention, the power saving apparatus 100 has a pair of ionization plates 30 at positions where the tourmaline intermediate layer 20 is sandwiched from above and below. Further, a pair of second tourmaline intermediate layers 50 are provided at positions sandwiching the pair of ionization plates 30 from above and below. That is, the ionization plate 30 is interposed on the boundary surface between the tourmaline intermediate layer 20 and the second tourmaline intermediate layer 50.

  The apparatus housing 10 is configured using a cover 12 and a housing 14 that are detachably coupled to each other, and can be joined to each other using, for example, solder, welding, or an adhesive, or Then, after forming a female screw at a corresponding portion of each corner of the cover 12 and the housing 14, the male screw can be used for coupling. The tourmaline intermediate layer 20, the pair of ionization plates 30, and the pair of second tourmaline intermediate layers 50 are formed in layers in a space formed inside by the cover 12 and the housing 14 (see FIG. 2 b). .

  Further, the cover 12 and the housing 14 need to be formed of a material having waterproofness and dustproofness. For example, the cover 12 and the housing 14 can be formed of a material such as iron, aluminum, or plastic.

  However, for insulation and stability, it is preferable to use a non-conductor, and it is preferable to use a plastic material. For example, the cover 12 and the housing 14 are most preferably formed of PC / ABS resin, but PC / ABS resin has a strength similar to that of iron and is a flame-retardant material. The material of the device housing 10 of the power saving device 100 has optimum conditions.

  On the other hand, when a plastic material is used, the inner wall of the device housing 10 can be galvanized. If galvanization is difficult, a paint of a zinc component (50% or more) may be used. Further, when a zinc component coating is applied, the coating thickness is preferably 1 mm or less.

  Further, when the cover 12 and the housing 14 are joined, it is preferable to apply silicone treatment to the joint 16 of the frame portion of the cover 12 and the housing 14 to ensure waterproofness. When the housing 14 and the housing 14 are fastened using male threads, the frame portions may not be in close contact with each other, and waterproofing with silicone becomes indispensable.

The tourmaline intermediate layer 20 accommodated in the apparatus housing 10 in a state of being laminated to a predetermined thickness is a layer made of a mixture of tourmaline powder, permanent magnet powder, and moisture (H ₂ O). Tourmaline is the most important element here.

  Permanent magnets are magnets that generate and maintain a stable magnetic field even when no electrical energy is supplied from the outside. Here, the permanent magnet powder should be a commercially available permanent magnet powder. In particular, it is desirable to use magnetite powder.

  Here, it is desirable that the tourmaline powder and the permanent magnet powder used in the tourmaline intermediate layer 20 use a powder of 325 mesh or more.

  The second tourmaline intermediate layer 50 is configured by removing permanent magnet powder from the tourmaline intermediate layer 20, and the upper second tourmaline intermediate layer 50a has a predetermined thickness toward the upper inner wall of the cover 12. The lower second tourmaline intermediate layer 50 b is arranged in a state of being laminated to a predetermined thickness toward the lower inner wall of the housing 14.

  The ionizing plate 30 is provided inside the apparatus housing 10 so as to be positioned above and below the tourmaline intermediate layer 20 (see FIG. 2b), and the upper ionizing plate 30a is formed of the tourmaline intermediate layer 20 and the upper second tourmaline intermediate layer 50a. When the cover 12 is separated from the housing 14 of the apparatus housing 10, the cover 12 is detached from the housing 14 together with the cover 12.

  On the other hand, the lower ionization plate 30b is located at the boundary surface between the tourmaline intermediate layer 20 and the lower second tourmaline intermediate layer 50b. When the cover 12 is separated from the housing 14 of the apparatus housing 10, the lower ionization plate 30b is located inside the housing 14. Remain.

  The pair of ionization plates 30a and 30b on the upper side and the lower side are each formed of a conductive metal such as copper or aluminum, and the ionization plates 30a and 30b made of a conductive metal are the tourmaline intermediate layer 20 and the second tourmaline intermediate. The layers 50a and 50b are in close contact with each other and function as metal plates at both ends of the capacitor.

Therefore, the electrons generated by the tourmaline intermediate layer 20 are charged by the function of the ionization plate 30 as a capacitor and then discharged, and the substance and the external input terminal filled inside the device via the conductive plate 40 described later. Make the space between the conductors. The conductive plate 40 is disposed in a state of being embedded in the tourmaline intermediate layer 20, and the material is preferably copper (purity 99.9%). Instead of the tourmaline intermediate layer 20, a Morganite powder layer (not shown) formed from a Morganite mineral powder may be used. Here, morganite is a mineral (Be ₃ Al ₂ Si ₆ O ₁₈ ) that is abundantly contained in river sand, smoke quartz, and the like, and is pulverized to form a powder of 325 mesh or 80 mesh. Used in. The function similar to that of the tourmaline intermediate layer 20 can be exhibited by the morganite powder layer.

  Although the conductive plate 40 is embedded in the tourmaline intermediate layer 20 containing moisture and may be oxidized by moisture, moisture is reduced by the action of reducing electrons discharged by the discharge action of the ionization plate 30 described above. Oxidation due to can be minimized.

  Therefore, oxidation of metal parts such as the conductive plate 40 accommodated in the power saving apparatus 100 can be minimized, and the lifetime of the apparatus can be extended. As the power line 60 that connects the conductive plate 40 and the power bus at the power supply end (not shown), several commercially available power lines can be used, and the power line conforms to a safety standard having a sufficient thickness. Is used. It is necessary that the one end portion 60a of the power line and the terminal 70 connecting the conductive plate 40 are securely fastened so that no gap is generated.

  A power line holding unit 62 that matches the power line 60 is used, so that when the housing 14 of the apparatus housing 10 and the power line 60 are connected, the internal moisture does not leak to the outside. It is securely sealed and fixed using an adhesive.

  The power saving apparatus 100 is an apparatus that generates surplus electrons by an electrical or chemical reaction. On the other hand, the power line 60 is composed of copper as a main component, and is in a neutral state in which the number of protons and electrons is the same under a current flowing condition. Therefore, when the power saving apparatus set 1000 supplies surplus electrons to the power line 60, the surplus electrons supplied to the power line 60 remain in the conduction band where the moving speed of the electrons is high. Here, the conduction band means an empty band immediately above the band gap in a system having a band gap (forbidden band or forbidden band). The band gap indicates an energy level from the top of the highest energy band (valence band) occupied by electrons in the band structure to the bottom of the lowest empty energy band (conduction band).

  In general, in a metal conductor, a free electron traveling around a conduction band causes a current to flow. If the number of free electrons increases in the conduction band and some surplus electrons remain in the conduction band having a higher moving speed, the resistance of the power line 60 decreases. Therefore, Joule heat generated by the resistance of the power line is reduced, and power consumption can be reduced.

  The surplus electrons fill holes that act as a resistance component in the power line 60 to improve the current flow of the power line 60, and the surplus electrons are not free electrons that flow while being restrained by protons. Therefore, the moving speed is relatively high.

  Due to the fast moving speed of such surplus electrons, surplus electrons are quickly introduced from the region where the harmonics are generated or the part where the electromagnetic waves are induced, and have a function of escaping, thereby wasting energy in the form of harmonics and electromagnetic waves. This can be suppressed.

  The reason for the generation of harmonics and electromagnetic waves is that the temporal density of electrons and protons in various electronic devices of the power line 60 and power system changes, and the surplus electrons suppress harmonics at an extremely fast speed. It plays a function of suppressing power loss.

  Furthermore, although the surplus electrons can move quickly in the power line 60, they do not move quickly when supplied from the power saving apparatus to the power line. This is because the power-saving device set 1000 of the present invention has substantially the same potential as that of the power line 60 and thus has no rapidly changing electric or magnetic field elements.

  However, due to the voltage applied to the power line 60, a difference in density of surplus electrons occurs in the power line 60, and only a minute current flows between the power saving device set 1000 and the power line 60 in the process of replenishing the density difference. Become.

  Here, the number of surplus electrons supplied from the power saving apparatus set 1000 to the power line 60 is negligibly small compared to the number of electrons existing in the copper constituting the power line 60, and the power system It has only a function of improving the power efficiency supplied at the time of loading when the power lines 60 are connected to each other.

  In addition, in carrying out the present invention, even if only one place in the power line 60 located on both sides with the secondary side as the center can be connected to the power saving apparatus set 1000, the power transmission efficiency can be improved. In such a case, the density of surplus electrons between the power lines 60 may be changed depending on the voltage difference applied to both the power lines 60. Therefore, the power lines 60 are located on both sides of the secondary side. It is thought that it is more efficient to connect the power saving apparatus set 1000 of the invention and supply surplus electrons.

  Furthermore, the power saving apparatus set 1000 according to the present invention supplies a small amount of surplus electrons to the power line 60 and supplements the density difference of the surplus electrons existing in the power line 60 as necessary. Has the advantage of being very small. Therefore, it can be easily inserted into a vacant space in the switchboard of an existing factory and produced, and can be installed without changing the layout of the existing factory.

  Furthermore, since the power saving apparatus set 1000 is attached in parallel to the power line 60, the power line 60 can be connected even when power is supplied to the power line 60.

  On the other hand, the power-saving device set 1000 can be made arbitrarily according to the degree of insulation required by the usage environment, or the size can be adjusted according to the supply quantity of surplus electrons required by the usage environment. Can be created arbitrarily.

  Furthermore, the power-saving device set 1000 of the present invention has a function of improving power transmission efficiency without causing any side effect that causes loss to the electrical device or power system, regardless of the connection to any electrical device or power system. . In particular, in an environment where an AC voltage is supplied, the surplus electrons supplied by the present invention have a function of reducing harmonic attenuation and the phase difference between voltage and current, thereby further improving power transfer efficiency. become.

  FIG. 3 is a configuration diagram of the power saving apparatus set 1000 according to the second embodiment of the present invention, and is a configuration diagram in the case of a single-phase three-wire system. As shown in FIG. 3, the power saving apparatus set 1000 includes a power saving apparatus 100, a case 200, an insulating plate 300, and a ground plate 500.

  The case 200 needs to be formed of a material having waterproofness and dustproofness. For example, the case 200 can be formed of a material such as plastic, stainless steel, and stainless steel plate. As described above, the power saving device 100 provided in the case 200 includes a mixture of a tourmaline mineral having permanent electrical characteristics and a permanent magnet powder having permanent magnetic characteristics. It is a device that realizes power saving of electric energy by improving the above.

  These power-saving devices 100 have a single-phase, three-wire power bus as a single module, and the three power-saving devices 100 are stacked in three stages up and down with their respective device outer surfaces in contact with each other. The power lines R, S, and T are electrically connected to the three power lines R, S, and T provided independently at the power supply terminals.

  The ground plate 500 is made of a copper plate, an aluminum plate, an iron plate, or the like, and is located between the two stacked power saving devices 100 and the outermost surface of the power saving device 100 located on the outermost side. That is, the outermost power-saving device 100 located at the uppermost stage and the lowermost stage is installed on the two outermost surfaces on the uppermost stage side and the lowermost stage side, and is electrically connected to the ground line G, respectively. The potential difference with the power saving device 100 is made close to 0 by coupling with the ground (earth).

  The insulating plate 300 is formed by molding a material such as plastic or rubber into a plate shape, between the ground plate 500 and the case 200 installed on the outermost surface on the uppermost side of the outermost power saving device 100, and This electrically insulates between the ground plate 500 and the case 200 installed on the outermost surface on the lowermost stage side of the outermost power saving apparatus 100.

  With such a configuration of the power saving apparatus set 1000, the ground plate 500 is connected to the ground (earth), and the amount of free electrons emitted due to the potential difference of the power saving apparatus 100 is increased, and the harmonic reduction effect is increased.

  FIG. 4 is a configuration diagram of the power saving apparatus set 1000 according to the third embodiment of the present invention, and is a configuration diagram in the case of a single-phase two-wire system. As shown in FIG. 4, the power saving device set 1000 includes a power saving device 100, a case 200, an insulating plate 300, and a ground plate 500.

  The case 200 needs to be formed of a material having waterproofness and dustproofness. For example, the case 200 can be formed of a material such as plastic, stainless steel, and stainless steel plate. The plurality of power saving devices 100 disposed inside the case 200 improve the movement and flow of electrons by using a mixture of a tourmaline mineral having permanent electrical characteristics and a permanent magnet powder having permanent magnetic characteristics. By doing so, it is a device that realizes power saving of electric energy.

  In these power saving apparatuses 100, the power bus is a single-phase two-wire system as a single module, and the two power saving apparatuses 100 are stacked in two stages in the vertical direction with the outer surfaces of the apparatuses contacting each other. The power lines L and N are disposed independently and electrically connected to the two power lines L and N provided at the power supply end.

  The ground plate 500 is made of a copper plate, an aluminum plate, an iron plate, or the like, and is the outermost surface of the power saving device 100 located between the three stacked power saving devices 100 and the outermost side. That is, the outermost power-saving device 100 located at the uppermost stage and the lowermost stage is installed on the two outermost surfaces on the uppermost stage side and the lowermost stage side, and is electrically connected to the ground line G, respectively. The potential difference with the power saving device 100 is made close to 0 by coupling with the ground (earth).

  The insulating plate 300 is formed by molding a material such as plastic or rubber into a plate shape, between the ground plate 500 and the case 200 installed on the outermost surface on the uppermost side of the outermost power saving device 100, and This electrically insulates between the ground plate 500 and the case 200 installed on the outermost surface on the lowermost stage side of the outermost power saving apparatus 100.

  With such a configuration of the power saving apparatus set 1000, the ground plate 500 is connected to the ground (earth), and the amount of free electrons emitted due to the potential difference of the power saving apparatus 100 is increased, and the harmonic reduction effect is increased.

  FIG. 5 is a diagram illustrating an installation example in the power saving apparatus set according to the embodiment of the present invention. As shown in FIG. 5, the power-saving device set 1000 is provided inside a power receiving panel 600 connected to the secondary side of the transformer TR, and is interposed between the air circuit breaker ACB and the wiring circuit breaker MCCB. Installed.

  The above-described air circuit breaker ACB (Air Circuit Breaker) is installed in the power receiving panel 600 to block power supply to each user unit of the building (for example, each floor of the building, each building of the apartment) in advance, It is a device that prevents the occurrence of risks due to electric leakage and overload.

  Specifically, the air circuit breaker ACB plays a role of protecting the low voltage line and protecting the transformer TR, such as short circuit current interruption, ground fault current interruption, overload current interruption, and low voltage interruption. Play a role.

  Further, the normal air circuit breaker ACB free from leakage or overload distributes the electric power supplied from the outside of the power receiving panel 600 via the power bus 610.

  The power bus 610 is connected to the power saving apparatus set 1000 via the four, three, or two power lines 60 according to the above-described three-phase four-wire system, three-phase three-wire system, or single-phase two-wire system. Electrically connected.

  The circuit breaker MCCB for wiring distributes the power distributed through the power bus to each user unit (for example, each floor of the building), that is, the power supply is shut off in advance immediately before the load is supplied, and there is no risk of leakage or overload. It is a device that prevents occurrence.

  For example, a circuit breaker MCCB (Molded Case Circuit Breaker) protects a low-voltage indoor line of 250V or less by automatically interrupting current when an overload and disconnection abnormality occurs.

  Table 1 below shows the reduction rate before and after the installation of the power saving apparatus set 1000, and FIG. 6 is a diagram showing the harmonic reduction efficiency of the power saving apparatus set according to the embodiment of the present invention. After installing the power-saving device set 1000, it can be seen that the harmonics are significantly reduced by the ground plate 500 connected to the ground and the electrical properties of the tourmaline.

  The technical idea of the present invention has been described with reference to the accompanying drawings. However, this is merely illustrative of a preferred embodiment of the present invention and does not limit the present invention. Further, it is obvious that any person having ordinary knowledge in this technical field can make various modifications and imitations without departing from the scope of the technical idea of the present invention.

  For example, a power saving device (Korean Patent No. 10-041931: Patent Document 4) filed and registered by the present applicant as an example of a power saving device constituting a power saving set has been filed by the applicant. It can also be applied to a published power saving device (Korean Patent Application Publication No. 2002-0028862), and in the figure, the power saving device is shown to be stacked one above the other. Can be stacked.

100: power saving device, outermost power saving device, 200: case, 300: insulating plate, 500: ground plate, 600: power receiving panel, 1000: power saving device set.

Claims (8)

Case and
Inside the case, the outer surfaces of the devices are placed in contact with each other, and the interior is filled with a mixture of tourmaline minerals having permanent electrical properties and permanent magnet powders having permanent magnetic properties. A plurality of power saving devices,
A grounding plate installed between the plurality of power saving devices stacked inside the case and on the outermost surface of the outermost power saving device located on the outermost side, and electrically connected to the ground wire,
A power-saving device set including the grounding plate installed on the outermost surface of the outermost power-saving device and an insulating plate provided between the case and electrically insulating. The power-saving device set according to claim 1,
The power saving device is:
A device housing;
A tourmaline intermediate layer that is a mixture layer of tourmaline powder, permanent magnet powder, and moisture (H ₂ O) housed inside the device housing;
An ionization plate of conductive metal located between the tourmaline intermediate layer inside the device housing;
And a conductive plate positioned in a state embedded in the tourmaline intermediate layer. In the power saving apparatus set according to claim 2,
And further comprising a second tourmaline intermediate layer that is a mixture layer of the tourmaline powder and the moisture located between the tourmaline intermediate layers inside the device casing,
The said ionization board is interposed in the interface of the said tourmaline intermediate | middle layer and said 2nd tourmaline intermediate | middle layer, The power saving apparatus set characterized by the above-mentioned. The power-saving device set according to claim 1,
The case is
Consists of any one of plastic, stainless steel, and stainless steel plate,
The insulating plate is
Composed of plastic or rubber,
The ground plate is
A power-saving device set comprising any one of a copper plate, an aluminum plate, and an iron plate. The power-saving device set according to claim 1,
The power saving device set is:
A power-saving device set that is connected to a power bus between an air circuit breaker and a circuit breaker inside a power receiving panel connected to a secondary side of the transformer. In the power saving apparatus set according to claim 5,
When the power bus is a single-phase two-wire system, the power saving device set is characterized in that two single modules of the power saving device are provided on two power lines and are electrically connected to each other. In the power saving apparatus set according to claim 5,
When the power bus is a single-phase three-wire system, the power saving device set is characterized in that three single modules of the power saving device are provided on three power lines and are electrically connected to each other. In the power saving apparatus set according to claim 5,
When the power bus is a three-phase four-wire system, the power saving device set is characterized in that four single modules of the power saving device are provided on four power lines and are electrically connected to each other.