KR20200053671A - Stationary type Electrical Outlet Device equipped with Short-range Wireless Communication Function and Power Saving Function by using Parallel Connection type Ferroelectrics - Google Patents

Abstract

The present invention relates to a stationary type electrical outlet device equipped with a power saving function by using parallel connection type ferroelectrics. The stationary type electrical outlet device having a power plug portion and an M (M >= 1) plug insertion portion and provided with at least two terminal insertion holes in the plug insertion portion includes: a ferroelectric mixture solidified into a predetermined geometric structure; a first conducting wire portion for electrically connecting a power contact provided at a first electrode portion designated to the ferroelectric mixture to a terminal of one side of the power plug portion; a second conducting wire portion for electrically connecting a power contact provided at a second electrode portion insulated from the first electrode portion to a terminal of the other side of the power plug portion; an M first wiring portion for electrically connecting an M wiring contact provided in the first electrode portion to an M first contact portion provided in a first terminal insertion hole of one side of the M plug insertion portion; an M second wiring portion for electrically connecting an M wiring contact provided in the second electrode portion to an M second contact portion provided in a second terminal insertion hole of the other side of the M plug insertion portion; a sensor portion for sensing a designated sensing value through the ferroelectric mixture by interworking with at least one of the conducting wire portion and the wire portion; a generating portion for generating designated output information through the sensed sensing value; and a communication portion for transmitting a short-range wireless signal including the output information.

Description

Stationary type Electrical Outlet Device equipped with Short-range Wireless Communication Function and Power Saving Function by using Parallel Connection type Ferroelectrics}

The present invention is inserted into a plug-in part of a wall-type outlet or other stationary-type outlet, and the power plug portion receiving AC power applied from the switchboard or distribution panel and the M (M≥1) number of plugs capable of inserting power plugs of electrical appliances or other outlets. Applied through the power plug unit while having a ferroelectric mixture produced using N (N≥2) designated materials and at least two electrode units arranged to be insulated from each other in a specified geometric relationship inside a stationary outlet device having a plug insertion unit. In addition to saving the AC power supplied to the electrical appliances or other outlets through the M plug insertion parts by connecting the AC power supply and the electrode parts in the ferroelectric mixture and the contact parts provided on the M plug insertion parts in parallel. Is the AC power supplied through the wall-type outlet or another stationary outlet? Also to multiple power saving and provides a stationary outlet device having a function to transmit a power-saving information in a local area, or transmitted to a wireless terminal in a local area via the ferroelectric mixture.

Conventionally, various outlet devices for power saving have been proposed. However, a conventional power-saving outlet device is provided in a form of blocking standby power by sensing the amount of power of an electric device connected to a plug insertion unit (Patent Publication No. 10-2010-0111089 (October 14, 2010), patent Publication No. 10-2011-0030081 (March 23, 2011), Patent Publication No. 10-2013-0081368 (July 17, 2013), Patent Registration Publication No. 10-1731266 (April 2017 24th) etc.).

However, the conventional power-saving outlet device only blocks the use of standby power when the power of the connected electric device is off, and saves power use when the power of the electric device is on. In particular, any conventional power-saving outlet device has a problem in that power consumption of other electrical devices in addition to the use of power of an electrical device connected to the corresponding outlet device cannot be saved at all.

The object of the present invention for solving the above problems is to insert a plug in the wall-type outlet or other stationary outlet, the power plug unit receiving AC power applied from the switchboard or distribution panel and the power of an electrical appliance or other outlet. Manufactured using N (N≥2) designated materials and at least two electrode parts arranged insulated from each other in a specified geometric relationship inside a stationary outlet device having M (M≥1) plug insertable parts capable of inserting a plug. An electric power or other product through the contact portion of the plug insertion portion by connecting in parallel the AC power applied through the power plug portion while the ferroelectric mixture is provided, the electrode portion in the ferroelectric mixture, and the contact portions provided on the M plug insertion portions in parallel. Absorbs harmonics and thermal noise from AC power applied to a stationary outlet. W At the same time as the primary power saving, the wall-type outlet or other stationary outlet that shares AC power applied from the switchboard or distribution panel while the power plug portion is inserted into the plug-in portion of the wall-type outlet or other stationary outlet is shared. Plugs of other wall-type outlets that share the AC power applied from the switchboard or distribution panel as well as secondary power saving by absorbing harmonics and heat noise of AC power applied to other electrical products in parallel through the contact part of the other plug insertion part. It also absorbs harmonics and heat noise of AC power applied to other electrical products in parallel through the insertion part in parallel to save power for the third time, and transmits the power saving information through the ferroelectric mixture at a short distance or transmits it to a short-range wireless terminal. Short-range wireless communication function and parallel connection It is to provide a stationary outlet device having a power saving function using the whole.

The stationary outlet device having a power saving function using a parallel-connected ferroelectric according to the present invention includes a power plug unit for receiving AC power and M (M≥1) plug insertion units for supplying AC power, and inserting the plug In a stationary outlet device having at least two terminal insertion holes of a specified structure at a designated position of a negative, in the specified weight percentage (wt (%)), N (N≥2) containing silicon (Si) and aluminum (Al) The specified mixture is mixed at a preset mixing ratio and oxidized in a low-temperature drying furnace while mixing and pulverized to produce an oxidizing mixture, and then fired and cooled at a predetermined temperature in an electric furnace to cool the resulting mixed mixture with a predetermined binder and a predetermined mixing ratio. After being liquefied by mixing with, the liquefied portion of at least two electrodes arranged to be insulated from each other in a specified geometric relationship The mixture is dried in close contact with the liquid, and the ferroelectric mixture produced by solidifying into a specified geometric structure, and the M first contact portions provided in the first terminal insertion holes of each side of the M plug insertion portions and the one side terminal of the power plug portion A first wiring part that is electrically connected to form a wiring for applying AC power to the M first contact parts, and the M second pieces provided in the second terminal insertion hole on the other side of each of the M plug insertion parts. A second wiring unit that electrically connects a contact portion and the other terminal of the power plug portion to form wiring for applying AC power to the M second contact portions, and a designated first of the electrode portions provided in the ferroelectric mixture. The first electrode part of the electrode part provided in the ferroelectric mixture, and a first connection part for electrically connecting the first contact part and the connection contact point provided in the electrode part The ferroelectric mixture is interlocked with at least one of a second connection part electrically connecting the second wiring part with a connection contact provided on a second electrode part that is insulated to form a specified geometrical relationship with the wiring part and the connection part. A sensor unit for sensing a designated sensing value including the amount of power used for power saving, a generating unit for generating designated operating information through the sensed sensing value, and transmitting a short-range wireless signal including the operating information or a designated short-range wireless And a communication unit transmitting the operation information to an app of a designated wireless terminal through communication.

According to the present invention, it is preferable that the specified weight percentage range includes silicon (Si) in the range of 10-40 wt (%) and aluminum (Al) in the range of 10-40 wt (%). Meanwhile, the sum of the weight percentages of the silicon (Si) and the aluminum (Al) is preferably within 60 (+5) wt (%). Meanwhile

According to the present invention, the N designated materials may further include at least one of iron (Fe) in the range of 5-20 wt (%) and magnesium (Mg) in the range of 5-20 wt (%).

According to the present invention, the N designated substances are zirconium (Zr) within 5 wt (%), sodium (Na) within 5 wt (%), potassium (K) within 5 wt (%), within 5 wt (%) Calcium (Ca), titanium (Ti) within 5 wt (%), zirconium boride (ZrB2) within 5 wt (%), titanium compound (TiB2) within 5 wt (%), titanium barium within 5 wt (%) ( BaTi).

According to the present invention, the mixed powder may be produced by preparing raw materials prepared for each N designated materials, and then mixing the prepared raw materials for each material at a mixing ratio corresponding to a specified weight percentage range and stirring while grinding.

According to the present invention, the mixed powder is prepared by preparing n (1 ≤ n ≤ N) ore raw materials containing N designated substances, and then mixing the prepared ore raw materials at a mixing ratio corresponding to a specified weight percentage range It can be produced by stirring while grinding.

According to the present invention, the mixed powder prepares i (1≤i≤N) ore raw materials including at least some of the N designated materials and is not included in the i ore raw materials or is insufficient in a specified weight percentage range After preparing j (1≤j≤N, N = i∪j) raw materials for each material, the prepared i ore raw materials and j raw materials for each material are mixed and crushed corresponding to a specified weight percentage range, and produced by stirring. Can be.

According to the present invention, the mixed powder is prepared by k (1 ≤ k ≤ N) waste raw materials containing N designated substances, and then mixing the prepared k waste raw materials at a mixing ratio corresponding to a specified weight percentage range. It can be produced by stirring while grinding.

According to the present invention, the mixed powder prepares p (1≤p≤N) waste raw materials containing at least some of the N designated substances and is not included in the p waste raw materials or lacks the specified weight percentage range. After preparing q (1≤q≤N, N = p∪q) raw materials for each material, the prepared p waste raw materials and q raw materials for each material are mixed and crushed by mixing corresponding to the specified weight percentage range and stirred to be produced. Can be.

According to the present invention, the mixed powder prepares raw materials from s (1 ≤ s ≤ N) ore raw materials and t (1 ≤ t ≤ N) waste raw materials containing at least some of the N designated substances, and After preparing raw materials for each of u (1≤u≤N, N = s∪t∪u) materials that are not included in the s ore materials and t waste raw materials or insufficient in the specified weight percentage range, the prepared s ore materials and It can be produced by mixing and mixing t waste raw materials and u raw materials for each material in a range corresponding to a specified weight percentage.

According to the present invention, the waste material may include at least one of the waste sludge of the solar panel and the ferroelectric mixture that has failed quality inspection.

According to the present invention, the mixed powder may be generated by pulverizing the mixed raw materials to a size of 100 mesh to 200 mesh so as to correspond to a specified weight percentage range.

According to the present invention, the oxidation mixture may be produced by oxidizing the mixed powder for 45 hours or more through dry air at 80 ° C (ㅁ 10 ° C) in a low temperature drying furnace.

According to the present invention, the firing mixture may be produced by firing the oxidizing mixture at a temperature of 890 ° C to 970 ° C in an electric furnace for 10 hours or more.

According to the present invention, the binder may include an inorganic compound that liquefies the mineral powder. On the other hand, the blending ratio is preferably the ratio of the binder to the firing mixture is within 10%.

According to the present invention, the geometrical relationship may include a relationship in which each electrode part is spaced apart from each other in a distance relationship of 1 cm to 1.5 cm in order to maximize the occurrence of electric polarization (or dielectric polarization) between mutually insulated electrode parts. .

According to the present invention, the geometrical relationship may include a relationship in which two designated electrode parts insulated from each other are arranged in parallel.

According to the present invention, the geometrical relationship may include a relationship in which two designated electrode parts that are insulated from each other are opposed to each other.

According to the present invention, the geometrical relationship may include a relationship in which two designated electrode parts insulated from each other are arranged in a hierarchical structure.

According to the present invention, the geometrical relationship may include a relationship in which the shortest distance in the vertical direction between the surface of each electrode part provided inside the ferroelectric mixture and the outer surface of the ferroelectric mixture is spaced at least 0.5 cm or more.

According to the present invention, the electrode part may include an electrode plate having a length of 3 cm or more, a width of 0.5 cm or more, and a thickness of 0.1 cm or more for each electrode part.

According to the present invention, the electrode portion may include a contact area in contact with the ferroelectric mixture at least 3.6 cm 2 or more for each electrode portion.

According to the present invention, the ferroelectric mixture may include a volume of at least 45 cm 3 or more.

According to the present invention, the insulation resistance between the two electrode parts is at least 100 MΩ or infinitely measured while a voltage of 1000 V (ㅁ 100 V) is applied to the two electrode parts arranged to be insulated from each other in a specified geometric relationship. It is desirable to be.

According to the present invention, the stationary outlet device may further include a storage unit for storing setting information for generating designated operation information using a sensing value sensed through the sensor unit.

According to the present invention, the sensor unit includes a sensor for sensing the amount of power used for power saving through the ferroelectric mixture, and the setting information uses power saving for a period of time through the ferroelectric mixture based on the sensing value sensed through the sensor unit. It may include period information for calculating the accumulated cumulative power amount or initialization date and time information of the accumulated power amount.

According to the present invention, the operation information may include at least one of power consumption information used for power saving through the ferroelectric mixture and cumulative power consumption information used for power saving for a period of time through the ferroelectric mixture.

According to the present invention, the short-range wireless signal may include a wireless signal broadcast at a short distance without specifying a receiver according to a specified short-range wireless standard.

According to the present invention, the communication unit includes a function of performing a pairing procedure with a designated wireless terminal according to a specified short-range wireless standard at least once and transmitting the operation information to the app of the paired wireless terminal through the short-range wireless communication. can do.

According to the present invention, free electrons flowing in a conductor by reducing the resistance component on the line applying the AC power by absorbing harmonics and heat noise of AC power applied to an electric product or other stationary power outlet connected to a stationary outlet through a ferroelectric mixture. By rapidly increasing the moving speed of the, there is an advantage of saving the power in use while using the power of the AC power using the stationary outlet.

According to the present invention, the conventional power saver simply saves power by blocking standby power, while a ferroelectric mixture is provided even when AC power is applied to an electrical appliance or other stationary power outlet connected to a stationary outlet as well as in an unacceptable standby power state. By maintaining the state connected to the line of the AC power applied from the switchboard or distribution panel by connecting the stationary outlet device connected to the conductor (for example, without blocking the standby power of the outlet device), the AC power supplied from the switchboard or distribution panel is shared. In addition to the secondary power saving by absorbing harmonics and heat noise of AC power applied to other electrical products in parallel through the contact portion of the wall-type outlet or another plug-in part of the other wall-mounted outlet, as well as AC power applied from the switchboard or distribution panel Another wall to be shared Through a plug insertion portion of the contact portion of the receptacle type harmonics and thermal noise of the AC power applied to the other electrical appliances also has the advantage of absorbing in parallel, the third power saving.

According to the present invention, there is an advantage of outputting the amount of power used for power saving through the ferroelectric mixture provided with the stationary outlet while using power using the stationary outlet or providing it to the wireless terminal through short-range wireless signals or short-range wireless communication.

1 is a view showing the configuration of a stationary outlet device according to an embodiment of the present invention.
2 is a block diagram showing the functional configuration of the operating module according to an embodiment of the present invention.
3 is a view showing a manufacturing process of the stationary outlet device according to an embodiment of the present invention.

Hereinafter, an operation principle of a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings and description. However, the drawings shown below and the descriptions described below are for preferred implementation methods among various methods for effectively describing the features of the present invention, and the present invention is not limited to the following drawings and description.

That is, the following embodiments correspond to preferred union type embodiments among the numerous embodiments of the present invention. In the following embodiments, specific configurations are omitted, or functions implemented in specific configurations are divided into specific configurations. The embodiments, or the embodiments of integrating the functions implemented in two or more configurations into any one configuration, the embodiments of replacing the operation sequence of a specific configuration, etc., are all the rights of the present invention, unless otherwise stated in the following embodiments. It is clear that it falls within the scope. Accordingly, it is clearly stated that various embodiments corresponding to a subset or a subset can be divided by retroactively filing the filing date of the present invention.

In addition, in the following description of the present invention, when it is determined that detailed descriptions of related known functions or configurations may unnecessarily obscure the subject matter of the present invention, detailed descriptions thereof will be omitted. In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to a user's or operator's intention or practice. Therefore, the definition should be made based on the overall contents of the present invention.

As a result, the technical spirit of the present invention is determined by the claims, and the following examples are one means for efficiently explaining the technical spirit of the present invention to those skilled in the art to which the present invention pertains. That's it.

1 is a view showing the configuration of a stationary outlet device 100 according to an embodiment of the present invention.

In more detail, this drawing 1 can be inserted into a wall-type outlet or a plug-in portion of another stationary outlet to insert a power plug 105 for receiving AC power applied from a switchboard or distribution panel and a power plug for an electrical appliance or other outlet. At least two electrode units (N≥2) specified materials and at least two electrode portions arranged to be insulated from each other in a specified geometric relationship inside the stationary outlet device 100 having M (M≥1) plug inserts 110 145) while providing a ferroelectric mixture 140 manufactured using the AC power applied through the power plug unit 105 and the electrode unit 145 and the M plug insertion unit 110 in the ferroelectric mixture 140 ) By connecting the contact portion 125 provided in parallel to the harmonics of the AC power applied to the electrical appliance or other stationary outlet through the contact portion 125 of the plug insertion portion 110 By absorbing noise in parallel, primary power saving and at the same time receiving AC power supplied from the switchboard or distribution panel while the power plug section 105 is inserted into the plug insertion section of the wall-type outlet or another stationary outlet In addition to the secondary power saving by absorbing harmonics and heat noise of AC power applied to other electrical products in parallel through the contact portion of the wall-type outlet or another plug-in part of the other wall-mounted outlet, the AC power supplied from the switchboard or distribution panel is supplied. Shows an embodiment of a conceptual diagram of a stationary outlet device 100 that absorbs harmonics and heat noise of alternating current power applied to other electrical products in parallel through a contact portion of a plug insertion part of another wall-mounted outlet that is shared in parallel and saves tertiary power. As one, grow up with ordinary knowledge in the technical field to which the present invention belongs , It may be possible to infer various implementation methods for the configuration of the stationary outlet device 100 (for example, some components are omitted, subdivided, or combined implementation methods) by referring to and / or modifying this drawing. The present invention comprises all the inferred implementation methods, and its technical characteristics are not limited to only the implementation methods illustrated in FIG. 1. On the other hand, for convenience, this figure 1 will illustrate the features of the present invention by showing the outlet device 100 having two plug inserts 110, but the present invention is not limited thereby, and the outlet device 100 The plug insertion unit 110 can be variously implemented from 1 to 6, and it is clearly revealed that more than 6 embodiments are possible in some cases.

The wall-mounted outlet device 100 of the present invention is inserted into a plug-in part of a wall-mounted wall outlet or another wall-mounted wall outlet, and the power plug 105 for receiving AC power supplied from a switchboard or distribution panel and a power plug of an electrical appliance or other outlet It is provided with M (M≥1) plug insertion portion 110 that can be inserted. The power plug portion 105 is formed with at least two terminals having a structure specified at a specified location, and the plug insertion portion 110 is also formed with at least two terminal insertion holes 115 having a structure specified at a specified location. . The position and shape of the terminal of the power plug portion 105 and the terminal insertion hole 115 of the plug insertion portion 110 have a structure that matches each other. Meanwhile, the power plug unit 105 may have at least one ground contact having a structure designated at a designated location. The plug insertion part 110 may also be formed with at least one ground part 120 having a structure designated at a designated position. Preferably, the structure of the power plug portion 105 and the plug insertion portion 110 has a structure corresponding to any one of 14 types of electric plugs according to the International Electronical Committee (IEC). Preferably, the present invention is not limited by the electric plug type. For example, in the case of the Republic of Korea, C and F types are applied among 14 types of electric plugs according to the International Electrotechnical Commission. For convenience, this figure 1 is based on the F type of the electrical plug type of the International Electrotechnical Commission.

The power plug portion 105 is inserted into a plug insertion portion of a wall-type outlet that is electrically connected to a distribution panel or distribution panel of an indoor or commercial facility or industrial facility or a plug insertion portion of another stationary outlet, whereby the power plug portion 105 The terminal of the wall-type outlet is electrically connected to a contact portion in the terminal insertion hole provided in the plug insertion portion of the wall-mounted outlet or another stationary-type outlet to receive AC power applied from the switchboard or distribution panel. On the other hand, according to the method, the power plug unit 105 is a ground contact for grounding by being electrically connected to a grounding part provided in a plug inserting part of a wall-type outlet or another plug-in part of a wall-mounted outlet that is electrically connected to a switchboard or distribution panel. It may further include a terminal. Preferably, the structure of the power plug section 105 or the position or structure of the terminal conforms to any one of the types of electrical plugs according to the International Electrotechnical Commission, whereby the present invention is not limited.

The plug inserting unit 110 can insert power plugs of various electrical appliances or other outlets provided in indoor or commercial facilities or industrial facilities, and when the power plugs of the electrical appliances or other outlets are inserted, the plugs are inserted into the power plug. At least two terminal insertion holes 115 capable of inserting provided terminals are provided in a designated structure at a designated position. Meanwhile, according to a method of implementation, the plug insertion part 110 may further include a ground part 120 and a ground wire part 135 that are electrically connected to a ground contact provided in the inserted power plug to be grounded. Preferably, the structure of the plug insertion portion 110 or the position or structure of the terminal insertion hole 115 follows any one of the types of electric plugs according to the International Electrotechnical Commission, whereby the present invention is not limited. .

Referring to FIG. 1, the stationary outlet device 100 presets N (N≥2) designated substances including silicon (Si) and aluminum (Al) in a specified weight percentage (wt (%)) range. After mixing and grinding at the mixing ratio, the mixed powder stirred is oxidized in a low-temperature drying furnace to produce an oxidizing mixture, and then calcined at a predetermined temperature in an electric furnace, cooled, and then the resulting calcined mixture is mixed with a designated binder at a preset mixing ratio to liquefy. After the liquid mixture is closely adhered to the at least two electrode parts 145 arranged to be insulated from each other in a specified geometric relationship, and then dried, the ferroelectric mixture 140 solidified into a specified geometry structure and the M plug inserts ( 110) By connecting the M first contacts 125 provided in the first terminal insertion hole 115 of one side and one terminal of the power plug portion 105 by electrically connecting the M pieces The first wiring unit 130 forming a wiring for applying AC power to the one contact unit 125 and the second terminal insertion hole 115 of the other side of each of the M plug insertion units 110 are provided. A second wiring part that electrically connects the M second contact parts 125 and the other terminal of the power plug part 105 to form wiring for applying AC power to the M second contact parts 125. The first connection part electrically connecting the first wiring part 130 and the connection contact provided at the designated first electrode part 145 among the electrode parts 145 provided in the ferroelectric mixture 140. (155), the first electrode portion 145 of the electrode portion 145 provided in the ferroelectric mixture 140 is formed in a specified geometric relationship with the second electrode portion 145 disposed insulated to be insulated Of the second connection portion 155 electrically connecting the contact point and the second wiring portion 130, and the wiring portion 130 and the connection portion 155 In conjunction with at least one, the ferroelectric mixture 140 senses a designated sensing value including the amount of power used for power saving, generates the specified operation information through the sensed sensing value, encodes it in a designated short-range wireless signal, and transmits it or transmits the specified short-range signal It includes an operating module 200 for processing at least one designated function including a function for transmitting to the app of the designated wireless terminal through wireless communication, the ferroelectric mixture 140 and the wiring 130 and the connection 155 And a body part 160 having an operating module 200 in a designated mounting space and realizing the external shape of the outlet device 100.

The ferroelectric mixture 140 is provided through at least two electrode parts 145 arranged to be insulated from each other in a specified geometric relationship with N (N≥2) designated materials included in accordance with a specified weight percentage (wt (%)) range. As a general term for a composition that is solidified and manufactured into a specified geometric structure, heat energy is generated after absorbing harmonics generated from a power system or a load device (for example, a motor) or the like and transmitted to the electrode unit 145 during application or use of AC power. By reducing the resistance component of the line due to the harmonics by emitting and converting to, the speed of movement of free electrons flowing in the conducting wire is rapidly increased to save power, and at the same time, the electrode is generated by a load device or an electric wire during use of the AC power. It absorbs the thermal noise transmitted to the unit 145 and converts it into thermal energy to emit it, thereby reducing the effective power of the load device or electric wire. It shall perform the functions.

The harmonic is a generic term for waves constituting a periodic repetitive waveform in addition to the fundamental wave of the AC power source. The periodic repetitive waveform is decomposed into waves having a frequency that is an integer multiple of the fundamental wave, and a wave whose frequency is t (t≥2) times the fundamental wave is called a t-th harmonic. On the other hand, in the case of AC power, harmonics inevitably occur when converting AC voltage through a transformer, operating a motor mounted in various electrical products, or oscillating electrical signals having frequencies in various electronic products. As it propagates along the line applying AC power, it increases the resistance component of the line and acts as a cause of rapidly decreasing the speed of movement of free electrons flowing in the conductor, which makes it possible to use more power for equal work. In particular, harmonics generated in the load device generate a voltage drop due to impedance from the power supply side (for example, a switchboard or a distribution panel) to the end of the load device, and this voltage drop generates a voltage distortion that distorts the voltage waveform, and The dwarf type is amplified and acts as 'cause of various relay malfunctions, malfunction of precision electronic devices, power factor reduction, noise and vibration, and damage and overheating of the device', causing enormous energy loss. On the other hand, in the case of an AC power source, the harmonics causing the above are mainly the third harmonic, the fifth harmonic, and the seventh harmonic, and the ferroelectric mixture 140 of the present invention is particularly the third harmonic and the fifth harmonic. And 7th harmonics. Load devices such as motors that generate harmonics in most household appliances (eg, refrigerators, fans, air conditioners, washing machines, etc.) provided indoors, or various commercial electric appliances provided in commercial facilities or various industrial facilities provided in industrial facilities. With the development of electronic communication technology, numerous electronic products that oscillate electrical signals having a frequency are provided. Therefore, harmonics are inevitably generated in places where most of the electricity including indoors, commercial facilities, or industrial facilities where AC power is applied is inevitable, and although there are differences depending on the cause and amount of occurrence of harmonics, most of them use electricity. Electricity is wasted by harmonics everywhere.

The thermal noise is a generic term for noise generated by thermal disturbance. In the case of a load device, heat is inevitably generated due to the phase difference and the starting current, where the current waveform is 90 degrees later than the voltage waveform, and heat noise is generated due to the heat generation. In the case of thermal noise, the higher the temperature, the larger the noise voltage and the wider the frequency distribution. The ferroelectric mixture 140 of the present invention absorbs the thermal noise transferred to the electrode portion 145 and converts it into thermal energy to release it. At this time, the ferroelectric mixture 140 does not absorb heat itself, but absorbs the frequency waveform of heat noise generated by heat, and converts and absorbs the absorbed heat noise into heat energy. Preferably, the ferroelectric mixture 140 can maintain the surface temperature within 18 (+2) ° C (within 18 ° C, within 20 ° C within the error range) during absorption and conversion into thermal energy by absorbing the harmonics and heat noise. .

According to the method of the present invention, the ferroelectric mixture 140 is without a separate circuit (e.g., a circuit that cancels the harmonics by generating the harmonics of the harmonics generated in the power system during application or use of AC power), and / or Or without a separate coil, and / or without a magnetic material, and / or without a separate magnetic force supply, and / or without a separate energy supply (e.g., far infrared rays, etc.), in a specified weight percentage (wt (%)) range only It is characterized by absorbing harmonics and heat noise applied to the electrode unit 145 by using a specified N number of specified materials.

The ferroelectric mixture 140 is mixed with silicon (Si) and aluminum (Al) of the specified weight percentage (wt (%)) range N specified substances at a predetermined mixing ratio and stirred while grinding to mix powder And oxidize the mixed powder in a low-temperature drying furnace to produce an oxidized mixture, calcining the oxidized mixture at a predetermined temperature in an electric furnace, and then cooling it to produce a calcined mixture, and the calcined mixture and the designated binder at a preset blending ratio. After mixing and liquefying, the liquefied mixture is liquid-tightly adhered to at least two electrode parts 145 arranged to be insulated from each other in a specified geometric relationship and then dried and solidified to a designated geometry.

According to an embodiment of the present invention, by using only the ferroelectric mixture 140, the harmonics and heat noise applied to the electrode portion 145 are absorbed by a predetermined ratio or more to save a predetermined power saving rate (eg, a refrigerator, a fan, an air conditioner, a washing machine). In order to achieve a power saving rate of 10% or more in an indoor environment to be used, the mixed powder has a specified weight percentage (wt (%)) range of the silicon (Si) among the N materials in a range of 10-40 wt (%). It includes, it is preferable that the specified weight percentage (wt (%)) range of the aluminum (Al) includes a 10 ~ 40 wt (%) range. In particular, the sum of the weight percentages of silicon (Si) and aluminum (Al) contained in the mixed powder is 60 (to absorb the harmonics and heat noise applied to the electrode portion 145 with only the ferroelectric mixture 140 over a predetermined ratio. +5) It is desirable to maintain within wt (%) (within 60 wt (%), within error range within 65 wt (%)).

According to the first mixture preparation example of the present invention, the mixed powder prepares raw materials prepared for each N designated materials, and then mixes the prepared raw materials for each material at a mixing ratio corresponding to a specified weight percentage range of the mixed powder It can be produced by stirring while crushing to a size of 100 mesh to 200 mesh through a grinder.

According to the second mixture preparation example of the present invention, the mixed powder is prepared by preparing n (1 ≤ n ≤ N) ore raw materials containing N designated substances, and then weight percentage of each of the ore raw materials On the basis of the prepared n ore raw materials may be produced by mixing with a mixing ratio corresponding to a specified weight percentage range of the mixed powder and pulverizing to a size of 100 mesh to 200 mesh through a grinder. In this case, the manufacturing cost of the ferroelectric mixture 140 may be significantly lower than when using raw materials manufactured for each material. However, even if it is an ore of the same name, the content of minerals varies depending on the mine or mountainous region, and the termination and content of additional substances contained in the ore are also different. Therefore, when manufacturing a mixed powder using only ore, the manufacturing cost may be lowered, but it may be difficult to control a specified weight percentage range of the mixed powder. Of course, if the content of the minerals contained in the n ores prepared for use as the raw material and the material types and contents of the adjunct match the specified weight percentage range of the mixed powder, it provides the specified power saving performance within the error range at the lowest manufacturing cost. The ferroelectric mixture 140 can be manufactured, but otherwise, the manufacturing cost is low, but the power saving performance may be lowered outside the error range.

According to a third exemplary embodiment of the present invention, the mixed powder prepares i (1≤i≤N) ore raw materials including at least some of N designated materials and i among the N designated materials After preparing raw materials for each of j (1≤j≤N, N = i∪j) materials that are not included in the ore raw materials or are not included in the i ore raw materials so that they do not match the specified weight percentage range of the mixed powder On the basis of the weight percentage of each ore contained in the ore raw materials, the prepared i ore raw materials and the j raw materials for each material are mixed at a mixing ratio corresponding to a specified weight percentage range of the mixed powder, and 100 mesh to 200 mesh through a grinder. It can be produced by stirring while crushing to the size of the. In this case, the manufacturing cost of the ferroelectric mixture 140 is lower than when using raw materials prepared for each material, and the specified weight percentage range of the mixed powder can be easily controlled.

According to a fourth exemplary embodiment of the present invention, the mixed powder comprises k (1≤k≤N) waste raw materials (eg, photovoltaic used for photovoltaic power generation) containing at least some of the N designated materials. After preparing the waste sludge of the photovoltaic panel generated during the manufacturing process of the panel, the waste sludge of the photovoltaic panel used for photovoltaic power generation, or the waste, or the ferroelectric mixture 140 that has failed quality inspection, etc. On the basis of the weight percentage of each contained material, the prepared k waste raw materials may be generated by mixing and mixing at a mixing ratio corresponding to a specified weight percentage range of the mixed powder to a size of 100 mesh to 200 mesh through a grinder and stirring. In this case, the manufacturing cost of the ferroelectric mixture 140 may be significantly lower than when using raw materials manufactured for each material.

According to a fifth exemplary embodiment of the present invention, the mixed powder comprises p (1≤p≤N) waste raw materials containing at least some of the N designated materials (for example, photovoltaic used for solar power generation) Prepare the waste sludge of the photovoltaic panel generated during the manufacturing process of the panel, or the waste sludge of the photovoltaic panel used for photovoltaic power generation or disposal, or a ferroelectric mixture (140, etc.) that has failed quality inspection, and among the N designated substances Q (1≤q≤N, N = p∪q) raw materials for each material that are not included in the p waste raw materials or do not match the specified weight percentage range of the mixed powder even if they are included in the p waste raw materials After preparation, the prepared p waste raw materials and q raw materials for each material based on the weight percentage of each material contained in the p waste raw materials are designated by weight of the mixed powder. It can be produced by mixing with a mixing ratio corresponding to the rate range and stirring while grinding to a size of 100 mesh to 200 mesh through a grinder. In this case, the manufacturing cost of the ferroelectric mixture 140 is significantly lower than the case of using raw materials prepared for each material, and the specified weight percentage range of the mixed powder can be easily controlled.

According to a sixth exemplary embodiment of the present invention, the mixed powder includes s (1 ≤ s ≤ N) ore raw materials and t (1 ≤ t ≤ N) wastes containing at least some of the N designated substances. Prepare the raw material and match the specified weight percentage range of the mixed powder even if it is not included in the s ore materials and t waste raw materials among the N designated materials or in the s ore materials and t waste raw materials. After preparing raw materials for u (1≤u≤N, N = s∪t∪u) materials that are not sufficiently insufficient, the prepared s pieces are based on the weight percentage of each ore material and t waste materials. By mixing ore materials and t waste raw materials and raw materials for each of u materials at a mixing ratio corresponding to a specified weight percentage range of the mixed powder, the mixture is stirred while crushing to a size of 100 mesh to 200 mesh through a grinder. Can be created. In this case, the manufacturing cost of the ferroelectric mixture 140 is lower than when using raw materials prepared for each material, and the specified weight percentage range of the mixed powder can be easily controlled.

On the other hand, when the mixed powder is prepared through at least one of the second to sixth mixture manufacturing examples, the typical ore raw materials or waste raw materials that can be secured in Korea or the types of adjuncts included in the raw materials When considering the B content, the mixed powder may include various additives included in the ore raw material or waste raw material. In this case, the sum of the weight percentages of silicon (Si) and aluminum (Al) contained in the mixed powder is 55 in order to absorb harmonics and heat noise applied to the electrode portion 145 with only the ferroelectric mixture 140 in a predetermined ratio or more. It can maintain a weight percentage within wt (%).

Meanwhile, according to the method of the present invention, N designated substances included in the mixed powder include iron (Fe) and 5-20 wt () in the range of 5-20 wt (%) in addition to the silicon (Si) and aluminum (Al). %) Range of magnesium (Mg) may further include at least one material. Meanwhile, the mixed powder may further include silicon carbide (SiC) in a range of 5 to 20 wt (%) depending on the type of ore contained in the raw material or the type of waste.

Meanwhile, according to the method of the present invention, the N designated substances included in the mixed powder are zirconium (Zr) within 5 wt (%), sodium (Na) within 5 wt (%), and 5 wt (%) in addition to the substances. Potassium (K) within, Ca (Ca) within 5wt (%), Titanium (Ti) within 5wt (%), Zirconium Boride (ZrB2) within 5wt (%), Titanium compound within 5wt (%) (TiB2), 5wt (%) or less may further include at least one of titanium barium (BaTi). Meanwhile, some of the substances within 5 wt (%) may be omitted, and the present invention is not limited thereby.

On the other hand, when the mixed powder is prepared through at least one of the second to sixth mixture manufacturing examples, the typical ore raw materials or waste raw materials that can be secured in Korea or the types of adjuncts included in the raw materials When considering the content of B, N designated substances included in the mixed powder are 26.8 (wt (%)) of silicon (Si), 26.0 (wt (%)) of aluminum (Al), and 9.50 (wt (%)) Magnesium (Mg), 10.20 (wt (%)) iron (Fe), 10.00 (wt (%)) silicon carbide (SiC), 3.20 (wt (%)) zirconium (Zr), 2.20 (wt ( %)) Sodium (Na), 4.60 (wt (%)) potassium (K), 2.20 (wt (%)) calcium (Ca), 1.00 (wt (%)) titanium (Ti), 2.00 ( wt (%)) of zirconium boride (ZrB2), 1.20 (wt (%)) of titanium compound (TiB2), and 3.10 (wt (%)) of titanium barium (BaTi).

On the other hand, if at least one of the first to sixth mixture preparation examples is mixed with a predetermined mixing ratio to match N specified substances to a specified weight percentage range through at least one mixture production example, and agitated and mixed powder is produced, The mixed powder is introduced into a low-temperature drying furnace, oxidized while supplying oxygen through dried air, and then cooled through nitrogen (N2) to produce a stabilized oxidation mixture in air. Preferably, it is preferable to oxidize the mixed powder for at least 45 hours through dried air at 80 ° C (ㅁ 10 ° C) in a low-temperature drying furnace to generate an oxidation mixture. That is, some of the N designated substances included in the mixed powder (eg, silicon (Si), sodium (Na), aluminum (Al), etc.) are water (eg, oxygen (eg, oxygen ( O2) and hydrogen (H), etc.) may ignite or explode, so it is preferable to prepare the oxidation mixture by sufficiently and slowly oxidizing it using dried air.

According to the method of the present invention, silicon (Si) among N designated substances contained in the mixed powder is oxidized to silicon dioxide (Si02), and the aluminum can be oxidized to aluminum oxide (AlO2). Meanwhile, among the N designated substances contained in the mixed powder, magnesium (Mg) may be oxidized to magnesium oxide (MgO), and iron (Fe) may be oxidized to iron oxide (Fe2O3). Other materials include zirconium oxide (ZrO2), sodium oxide (NaO2), potassium oxide (K2O), calcium oxide (CaO), titanium oxide (TiO2), zirconium boride (ZrB2), titanium compound (TiB2), It can be oxidized with barium titanate (BaTiO3) or the like. The oxidizing mixture containing the oxidized material maintains a stable state even in a high humidity state in air. Meanwhile, when the material contained in the mixed powder is in a pre-oxidized state, the oxidation process can be omitted, and the present invention is not limited thereby.

When the oxidizing mixture is produced, the oxidizing mixture is calcined for 10 hours or more at a temperature of 890 ° C to 970 ° C in an electric furnace and cooled through nitrogen (N2) to produce a calcined mixture. Through the firing process, the firing mixture can maintain a stable state in any environment in the air, and in particular, the properties of the dielectric are stably activated. On the other hand, when the material contained in the mixed powder is in a stabilized state by being pre-oxidized or in the stabilized state after the oxidation mixture is oxidized, the firing process may be omitted, and the present invention is not limited thereby.

When the calcined mixture is produced, a liquid mixture is produced by combining the designated binder (eg, an inorganic compound to liquefy by combining mineral powders) and the calcined mixture at a predetermined mixing ratio to liquefy. Here, the blending ratio of the firing mixture and the binder is preferably a ratio of the binder to the firing mixture is less than 10%.

Geometry designated to insulate at least two electrode parts 145 made of a highly conductive metal material (for example, copper (Cu), etc.) in a frame made of a designated geometry structure to produce a ferroelectric mixture 140 having a specified geometry. Arranged and fixed in relation to each other, a manufacturing frame having a connection contact for electrically connecting the designated connection portion 155 to one side of the electrode portion 145 is prepared. Preferably, the fabrication frame is provided with each contact so that the connecting contact is exposed to the outside of the ferroelectric mixture 140 when the liquid mixture is poured and dried to produce the ferroelectric mixture 140.

According to an embodiment of the present invention, the geometrical relationship of arranging the electrode portions 145 in the ferroelectric mixture 140 allows each electrode portion 145 to maximize the occurrence of electric polarization (or dielectric polarization) between the electrode portions 145. It is preferable to include a relationship that is spaced apart from each other in a distance relationship of 1 cm to 1.5 cm. For example, when an AC power of 250V / 16A is applied to two designated electrode parts 145 provided in the ferroelectric mixture 140, electric polarization (or dielectric polarization) between the electrode parts 145 is activated. The interval is 0.9 cm ~ 2.2 cm, according to the applicant's experiment, when the gap between the two electrode parts 145 provided in the ferroelectric mixture 140 is 1 cm ~ 1.5 cm, the electric polarization (or dielectric polarization) phenomenon Can be maximized. On the other hand, even if the interval between the electrode portion 145 is 0.9cm ~ 2.2cm clearly reveals that it can be attributed to the scope of the present invention.

On the other hand, according to the method of the present invention, as soon as the AC power is applied to the two electrode portions 145 provided in the ferroelectric mixture 140, the phenomenon of electric polarization (or dielectric polarization) is not maximized, and the applicant's experiment According to the above, the electric polarization (or dielectric polarization) phenomenon is maximized after at least 7 minutes (preferably, 10 minutes or more) has elapsed after AC power is applied to each electrode portion 145 of the ferroelectric mixture 140, or The maximized state can be kept stable.

According to an embodiment of the present invention, it is preferable that the geometrical relationship of arranging the electrode portions 145 in the ferroelectric mixture 140 includes a relationship in which two designated electrode portions 145 are disposed in parallel. For example, when the cross section of the electrode portion 145 provided in the ferroelectric mixture 140 is '-', the two electrode portions 145 provided in the ferroelectric mixture 140 are as shown in '--'. It is preferred to be provided in a parallel relationship. Alternatively, when the cross section of the electrode portion 145 provided in the ferroelectric mixture 140 is' | ', the two electrode portions 145 provided in the ferroelectric mixture 140 are' | It is desirable to be provided in a parallel relationship such as | '.

According to the implementation method of the present invention, it is preferable that the geometrical relationship of arranging the electrode portions 145 in the ferroelectric mixture 140 includes a relationship in which two designated electrode portions 145 insulated from each other are opposed to each other. For example, when the cross section of the electrode portion 145 provided in the ferroelectric mixture 140 is '-', the two electrode portions 145 provided in the ferroelectric mixture 140 are as shown in '--'. It is desirable to be provided in an opposing relationship. Alternatively, when the cross section of the electrode portion 145 provided in the ferroelectric mixture 140 is' | ', the two electrode portions 145 provided in the ferroelectric mixture 140 are' | It is preferably provided in an opposite relationship, such as | '.

According to an embodiment of the present invention, the geometrical relationship of arranging the electrode portion 145 in the ferroelectric mixture 140 may include a relationship in which two designated electrode portions 145 are arranged in a hierarchical structure. For example, when the cross section of the electrode portion 145 provided in the ferroelectric mixture 140 is '-', the two electrode portions 145 provided in the ferroelectric mixture 140 have a relationship of '-_' B. It can be arranged in the same hierarchical structure as '_-'.

According to the method of the present invention, the geometric relationship of arranging the electrode portion 145 in the ferroelectric mixture 140 is the surface of each electrode portion 145 provided inside the ferroelectric mixture 140 and the ferroelectric mixture 140 It is preferable to include a relationship in which the shortest distance in the vertical direction between the outer surfaces of) is spaced at least 0.5 cm or more.

According to the extended implementation method of the present invention, the ferroelectric mixture 140 is electrically connected to the ground wire portion 135 connected to the ground portion 120 in addition to the electrode portion 145 electrically connected to the connection portion 155. And it may further include a conductive electrode electrically connected to the ground wire portion 135 connected to the ground contact of the power plug portion 105, whereby the present invention is not limited.

According to an embodiment of the present invention, since the harmonics and heat noise are transmitted along the surface of a conductive metal material, and the ferroelectric mixture 140 is made of a rectangular parallelepiped structure, the electrode part 145 forms an electrode plate shape of a specified geometry structure. It is preferred to include. Preferably, in the case of supplying AC power of 250V / 16A through the outlet device 100, the electrode part 145 is provided with each electrode part (145) in order to absorb harmonics and heat noise over a predetermined ratio with only the ferroelectric mixture 140. 145) It is preferable to include an electrode plate having a length of 3 cm or more, a width of 0.5 cm or more, and a thickness of 0.1 cm or more. However, the numerical value of the geometry of the electrode plate is a minimum numerical value for absorbing harmonics and heat noise over a predetermined ratio with the ferroelectric mixture 140 only under the AC power condition of 250V / 16A, and the electrode portion 145 The numerical value of the geometry is adjustable in a direction in which the contact area between the electrode part 145 and the ferroelectric mixture 140 increases. On the other hand, if the amount of voltage supplied through the outlet device 100 is set to a certain percentage greater than 250V or the amount of current to be supplied through the outlet device 100 is set to a certain percentage greater than the 16A, the geometry of the electrode section 145 The minimum numerical value for can be adjusted in a form that can calculate an external area that is larger than a predetermined ratio by the calculated numerical value.

According to an embodiment of the present invention, the electrode portion 145 and the ferroelectric mixture 140 are in contact with each other in order to absorb harmonics and heat noise applied to the electrode portion 145 with only the ferroelectric mixture 140 over a predetermined ratio. It is preferable to maintain the contact state over the area. Preferably, in the case of supplying AC power of 250V / 16A through the outlet device 100, the electrode portion 145 contacts at least 3.6 cm 2 or more for each electrode portion 145 with the ferroelectric mixture 140 It is preferred to include an area. For example, when the geometry of the electrode portion 145 is 3 cm long, 0.5 cm wide, and 0.1 cm thick, both ends of the electrode portion 145 are formed with a ferroelectric mixture 140 to form a designated contact point. Since it may not be in contact, it is preferable that the contact area in which the electrode portion 145 of the geometric structure contacts the ferroelectric mixture 140 is 3.6 cm 2 or more. However, the numerical value of the contact area of the electrode plate is a minimum numerical value for absorbing harmonics and heat noise over a predetermined ratio only with the ferroelectric mixture 140 under the AC power condition of 250V / 16A, and contacting the electrode portion 145 The numerical value of the area is adjustable in the direction in which the contact area where the electrode part 145 and the ferroelectric mixture 140 contact increases, and the electrode part 145 and the ferroelectric mixture 140 in the ferroelectric mixture 140 The larger the contact area in contact, the more stably the harmonics and heat noise can be absorbed over a specified ratio. On the other hand, when the amount of voltage supplied through the outlet device 100 is set to a certain percentage greater than 250V or the amount of current to be supplied through the outlet device 100 is set to a certain percentage greater than the 16A, the contact area of the electrode unit 145 The minimum numerical value for can be adjusted to a form capable of calculating a contact area that is larger than a predetermined ratio by the calculated numerical value.

According to an embodiment of the present invention, it is preferable that the ferroelectric mixture 140 maintains a volume greater than or equal to a specified volume in order to absorb harmonics and heat noise applied to the electrode portion 145 with only the ferroelectric mixture 140 over a specified ratio. Do. Preferably, when the 250V / 16A power is supplied through the outlet device 100, the geometry of the electrode portion 145 is 3 cm or more, 0.5 cm or more in width, 0.1 cm or more in thickness, and the ferroelectric mixture 140 At least two electrode parts 145 are disposed to be insulated from each other in a state of being spaced at least 1 cm or more, and the distance between the surface of each electrode part 145 and the surface of the ferroelectric mixture 140 is at least 0.5 cm or more. The volume of the ferroelectric mixture 140 is 9.9 cm 3 or more numerically, and considering the error value, the geometry for absorbing harmonics and heat noise applied to the electrode portion 145 with only the ferroelectric mixture 140 over a specified ratio The volume of the ferroelectric mixture 140 including the two electrode parts 145 including the structure preferably includes a volume of at least 10 cm 3 or more. However, the numerical value of the volume of the ferroelectric mixture 140 is a minimum numerical value for absorbing harmonics and heat noise at a specified ratio or more with the ferroelectric mixture 140 only under the AC power condition of 250V / 16A, and the ferroelectric mixture 140 The numerical value of the volume of can be adjusted in the direction in which the volume of the ferroelectric mixture 140 increases, and the larger the volume of the ferroelectric mixture 140, the more stable the harmonics and heat noise can be absorbed over a specified percentage. .

On the other hand, the amount and size of the harmonics and heat noise to be absorbed through the electrode portion 145 provided in the ferroelectric mixture 140 are the number and load of loads supplied through the plug insertion portion 110 of the outlet device 100. Proportional to. According to the applicant's experiment, when the volume of the ferroelectric mixture 140 is within 10 cm 3, harmonics and heat noise generated from a load device within 2 motors (for example, within 1 per 5 cm 3) rotating the fan blades are designated. It is confirmed that it can absorb more than a certain ratio. Accordingly, if the number of load devices per plug insertion part 110 of the outlet device 100 is averaged to 1.5, and the number of plug insertion parts 110 provided in the outlet device 100 is calculated to be maximum 6, the ferroelectric It is preferable that the volume of the ferroelectric mixture 140 for absorbing harmonics and heat noise applied to the electrode portion 145 with only the mixture 140 at a predetermined ratio or more includes a volume of 45 cm 3 or more.

Meanwhile, in the present invention, the ferroelectric mixture 140 provided in the outlet device 100 absorbs only harmonics and heat noise generated through a load device supplied with power through the plug insertion portion 110 of the outlet device 100. Rather, it is characterized by absorbing harmonics and heat noise generated through other load devices that do not receive power through the plug insertion unit 110 but share AC power applied from the switchboard or distribution panel, and consequently, the The ferroelectric mixture 140 provided in the outlet device 100 basically absorbs harmonics and heat noise generated from a plurality of load devices. On the other hand, the number of load devices operating simultaneously in a normal electric use environment excluding some commercial facilities or industrial facilities where load devices are concentrated is within 9, and the ferroelectric mixture for absorbing harmonics and heat noise generated through the above specified ratios It is preferable that the volume of 140 includes a volume of 45 cm 3 or more. However, the numerical value of the volume of the ferroelectric mixture 140 is a minimum numerical value for absorbing harmonics and heat noise at a predetermined ratio or more with the ferroelectric mixture 140 only in a normal electric use environment, and the volume of the ferroelectric mixture 140 The numerical value of can be adjusted in the direction in which the volume of the ferroelectric mixture 140 increases, and the larger the volume of the ferroelectric mixture 140, the more stable the harmonics and heat noise can be absorbed over a specified ratio.

Meanwhile, according to an embodiment of the present invention, the geometry of the outer shape of the ferroelectric mixture 140 may be variously adapted according to the space inside the outlet device 100 on which the ferroelectric mixture 140 is mounted.

According to the first ferroelectric mounting method of the present invention, the ferroelectric mixture 140 is provided in the front portion of the body portion 160 receiving AC power through the power plug portion 105 as in the embodiment of FIG. 1 Can be.

According to the second ferroelectric mounting method of the present invention, the ferroelectric mixture 140 may be provided on a side portion of the body portion 160 corresponding to at least one side portion of both sides of the plug insertion portion 110. .

According to the third ferroelectric mounting method of the present invention, the ferroelectric mixture 140 may be provided below the body portion 160 corresponding to the bottom of the plug insertion portion 110.

According to the fourth ferroelectric mounting method of the present invention, the ferroelectric mixture 140 may be provided on the rear portion of the body portion 160 corresponding to the opposite side of the portion supplied with AC power through the power plug portion 105. have.

According to an embodiment of the present invention, the fabrication frame is provided with an internal space for forming a geometric structure capable of mounting or fixing the ferroelectric mixture 140 in a designated mounting space formed in the body portion 160 of the outlet device 100. It is preferred to include.

When the production frame is prepared, the liquid mixture is poured into the production frame and the liquid mixture is in close contact with the electrode portion 145 disposed in a specified geometric relationship while being dried at room temperature, and the designated geometry structure corresponding to the frame is dried. The solidified ferroelectric mixture 140 is prepared.

According to an embodiment of the present invention, in the state in which the liquid mixture is poured into the production frame, before the solidification of the liquid state proceeds, vibration of the specified frequency is applied to the production frame to void the liquid mixture in the electrode part 145. Or, it can be processed to be tightly adhered.

When the liquid mixture poured into the production frame is dried at room temperature and solidified, the production frame is removed to separate the solidified ferroelectric mixture 140, and a designated quality inspection is performed.

According to an embodiment of the present invention, the electrode portion 145 of the ferroelectric mixture 140 is applied with a voltage of 1000 V (ㅁ 100 V) to two electrode portions 145 arranged to be insulated from each other in a specified geometric relationship. It is preferable that the insulation resistance between the two electrode parts 145 is measured at least 100 MΩ or infinitely.

According to the practice method of the present invention, the ferroelectric mixture 140 preferably contains a compressive strength of 350 to 460 kgf / cm 2 and a tensile strength of 27 to 35 kgf / cm 2 in a solidified state. Therefore, the solidified ferroelectric mixture 140 should not have any cracked or cracked parts. To confirm this, a visual inspection or designated non-destructive inspection may be performed.

When the ferroelectric mixture 140 is produced through the above process, the M plugs are inserted while the ferroelectric mixture 140 is mounted or fixed in a mounting space formed inside the body 160 of the outlet device 100. The M first contact parts are electrically connected to the M first contact parts 125 provided in the first terminal insertion hole 115 on one side of each part 110 and one terminal of the power plug part 105, respectively. The first connection part 155 electrically connected to the first wiring part 130 forming the wiring for applying the AC power to 125 is designated first among the electrode parts 145 provided in the ferroelectric mixture 140. At the same time as being electrically connected to the connection contact provided on the electrode portion 145, the M second contact portions 125 provided in the second terminal insertion hole 115 on the other side of each of the M plug insertion portions 110 ) And the other terminal of the power plug 105 by electrically connecting An electrode unit provided in the ferroelectric mixture 140 has a second connection unit 155 electrically connected to the second wiring unit 130 forming a wiring for applying AC power to the M second contact units 125 ( 145) of the first electrode part 145 and formed a specified geometrical relationship, electrically connected to a connection contact provided in the second electrode part 145 arranged to be insulated, and equipped with an operating module 200 to mount the outlet device. Produce (100).

According to an embodiment of the present invention, the connection contacts of the electrode portions 145 provided in the ferroelectric mixture 140 are provided in the terminal insertion holes 115 for each of the M plug insertion portions 110 through designated connection portions 155. By electrically connecting the provided M contact parts 125 and the electrically connected wiring part 130, the outlet device 100 is provided with an electrical product or other stationary outlet through the contact part 125 of the plug insertion part 110. It is possible to perform the function of primary power saving by absorbing harmonics and heat noise of AC power applied in parallel.

On the other hand, according to the embodiment of the present invention, by electrically connecting the connection contact of the electrode portion 145 provided in the ferroelectric mixture 140 with the terminal of the power plug portion 105, the outlet device 100 is the Even when the switch 150 is switched off, the power plug 105 is inserted into a plug insertion part of a wall-type outlet or another stationary outlet and AC power is applied from the switchboard or distribution panel. Secondary power saving by parallelly absorbing the harmonics and heat noise of AC power applied to other electrical products through the contact part of the wall-type outlet or other plug-in part of the other wall-mounted outlet that shares AC power applied from the switchboard or distribution panel is Of course, the plug insertion part of the other wall-type outlet that shares the AC power applied from the switchboard or the distribution panel It can also perform the function of tertiary power saving by absorbing harmonics and heat noise of AC power applied to other electric products in parallel through the contact unit in parallel.

According to an embodiment of the present invention, the stationary outlet device 100 may include a switch unit 150 that supplies power to the M plug insertion units 110, in which case the switch unit 150 is It is preferably provided between the wiring 130 and the ferroelectric mixture 140.

According to an embodiment of the present invention, by providing the switch unit 150 between the wiring unit 130 and the ferroelectric mixture 140, the outlet device 100 switches off the switch unit 150 ( Off) Even when the power plug unit 105 is inserted into a wall-type outlet or a plug-in unit of another stationary outlet, AC power is applied from the switchboard or distribution panel while AC power is applied from the switchboard or distribution panel. In addition, the second power-saving as well as the AC power applied from the switchboard or distribution panel by absorbing harmonics and heat noise of AC power applied to other electrical products in parallel through the contact portion of the wall-type outlet or another plug-in part of another stationary outlet. It is applied to other electrical appliances through the contact part of the plug insertion part of the other wall-type outlet that receives the Harmonic current of the power and the thermal noise can also be absorbed in parallel to perform the power saving function to the third.

On the other hand, according to the method of the present invention, the ferroelectric mixture 140 has a predetermined time (for example, the ratio of absorbing harmonics and thermal noise is less than a certain ratio at the time when AC power is supplied to the electrode unit 145) After a minimum of 1 hour or more, typically 3 hours or more) has elapsed, the ratio of the ferroelectric mixture 140 absorbing harmonics and heat noise reaches a maximum value and maintains the state, which is applied to the electrode unit 145 When the AC power is cut off, the ratio of absorbing the harmonics and heat noise is initialized. Therefore, unlike the conventional power saving method that cuts off standby power, the outlet device 100 must maintain a state in which AC power is applied to the ferroelectric mixture 140 through the power plug unit 105 to maximize the power saving function. It has retained characteristics.

Figure 2 is a block diagram showing the functional configuration of the operating module 200 according to an embodiment of the present invention.

In more detail, FIG. 2 is a block diagram showing the functional configuration of the operation module 200 mounted on the stationary outlet device 100 of FIG. 1, and those skilled in the art to which the present invention pertains, By referring to and / or modifying this figure 2, various implementation methods (for example, some configuration parts are omitted, subdivided, or combined implementation methods) for the functional configuration of the operation module 200 may be inferred. The invention includes all the inferred implementation methods, and its technical characteristics are not limited to only the implementation methods illustrated in FIG. 2.

Referring to FIG. 2, the operation module 200 is used for power saving through the ferroelectric mixture 140 in conjunction with at least one of the wiring unit 130 and the connection unit 155 provided in the stationary outlet device 100. A sensor unit 205 for sensing the designated sensing value including the amount of power, a generating unit 210 for generating the designated operating information through the sensed sensing value, and transmitting or designating a short-range wireless signal including the operating information It includes a communication unit 235 for transmitting the operation information to the app of the wireless terminal designated through short-range wireless communication, and further includes an output unit 215 for outputting the operation information, designated through the sensor unit 205 Further comprising a storage unit 225 for storing the setting information for generating the specified operation information by sensing the sensing value. On the other hand, the operation module 200 further includes a power supply unit 220 that generates a specified operation power in conjunction with at least one of the wiring unit 130 and the connection unit 155 and applies it to each component of the operation module 200, , It may further include an operation unit 230 for receiving a user operation.

The power supply unit 220 is connected to at least one of the wiring unit 130 and the connection unit 155 provided in the stationary outlet device 100, receives AC power, generates designated operation power, and configures each of the operating modules 200. We approve with wealth. Preferably, each component of the operation module 200 may use DC power as an operating power, in which case the power unit 220 is applied in conjunction with at least one of the wiring unit 130 and the connection unit 155. The rectified AC power may be rectified to DC power of one or more designated voltage values and current values to be applied to each component of the operation module 200.

According to an embodiment of the present invention, the power supply unit 220 may include a battery that charges and stores the applied operating power, and in this case, the operation module 200 is constant even when the AC power is not applied. Can operate for a period.

The sensor unit 205 includes a power amount sensor unit 205 having a power amount measurement sensor for sensing the amount of power and a converter for converting an analog value sensed through the power amount measurement sensor into a digitized sensing value. Preferably, the sensor unit 205 interlocks the power measurement sensor to at least one of the wiring unit 130 and the connection unit 155 provided in the stationary outlet device 100, and the ferroelectric mixture through the power measurement sensor. Through 140, a sensing value including the amount of power used for power saving is sensed.

Meanwhile, according to an embodiment of the present invention, the sensor unit 205 includes a harmonic sensor unit 205 having a harmonic sensor for sensing harmonics and a converter for converting an analog value sensed through the harmonic sensor into a digitized sensing value. It may further include. In this case, the sensor unit 205 interlocks the harmonic sensor to at least one of the wiring unit 130 and the connection unit 155 provided in the stationary outlet device 100, and the ferroelectric mixture 140 through the harmonic sensor. Through this, a sensing value including the harmonics absorbed may be sensed.

The storage unit 225 stores designated setting information set to generate designated operation information through a sensing value sensed through the sensor unit 205. Preferably, the setting information (or at least a part of the setting information) may be stored in the storage unit 225 at the time of manufacture of the outlet device 100 (or the operating module 200).

According to an embodiment of the present invention, the storage unit 225 may store designated setting information (or at least some information of setting information) set by the user. Preferably, the output unit 215 outputs an interface for receiving the specified setting information, the operation unit 230 inputs the setting information based on the interface, and the storage unit 225 is the operation unit The setting information input through 230 may be stored in a designated storage area.

The generation unit 210 generates designated operation information to be output through the output unit 215 using the sensing value sensed through the sensor unit 205.

According to an embodiment of the present invention, the generation unit 210 may generate operation information including a sensing value sensed through the sensor unit 205. Preferably, the generating unit 210 includes operating information including power amount information corresponding to a sensing value sensed through the sensor unit 205 (eg, power amount used for power saving through the ferroelectric mixture 140). Can be created.

According to an embodiment of the present invention, when setting information for generating the operation information specified in the storage unit 225 is stored, the generating unit 210 is through the sensor unit 205 based on the stored setting information. The designated operation information may be generated using the sensed value. If the setting information for calculating the cumulative power amount information in the storage unit 225 (for example, to initialize the cumulative power amount or period information for calculating the cumulative power used for a certain period of time through the ferroelectric mixture 140) When temporary information, etc.) is stored, the generating unit 210 may use the setting information to generate operating information including cumulative power consumption information for a certain period of time through the ferroelectric mixture 140.

On the other hand, setting information (for example, rate information per power amount (or cumulative power amount)) for calculating electric charges using power amount information or cumulative power amount information in the storage unit 225, progressive information for applying a progressive agent for each designated progressive section, etc. ) Is stored, the generator 210 may generate operation information including charge information corresponding to the amount of power used for power saving or cumulative amount of power used for power saving for a period of time based on the setting information.

On the other hand, according to the method of the present invention, the sensor unit 205 includes a harmonic sensor that senses harmonics, and a sensing value (eg, 3rd harmonic, 5th harmonic) that senses a specified harmonic through the sensor unit 205. When the order of harmonics, such as 7th harmonics, the frequency band of harmonics, the intensity (or amplitude) of harmonics, the amount of harmonics, etc.) is sensed, the generator 210 senses the sensed through the sensor unit 205. Generate operation information including harmonic information corresponding to a value (for example, harmonic information including one or more of the order, frequency band, intensity (or amplitude), and harmonic current amount of the harmonics absorbed through the ferroelectric mixture 140) can do. If the setting information for calculating the cumulative harmonic information in the storage unit 225 (for example, to initialize the cumulative harmonic accumulation or period information for calculating the cumulative harmonics accumulated for a certain period through the ferroelectric mixture 140) Temporary information, etc.) is stored, the generating unit 210 uses the setting information to generate operating information including cumulative harmonic information corresponding to the harmonics accumulated and absorbed for a period of time through the ferroelectric mixture 140. Can be.

Meanwhile, when at least one designated operation information is generated through the generation unit 210, the communication unit 235 transmits a short-range wireless signal including the operation information according to a specified wireless standard or a designated wireless through a specified short-range wireless communication. The operation information is transmitted to the terminal app. Meanwhile, the storage unit 225 transmits the generated operation information to a designated storage area for a predetermined time (eg, the generated operation information is transmitted or transmitted through the communication unit 235 or until the next operation information is generated). It can be stored and managed.

According to an exemplary embodiment of the present invention, the communication unit 235 may encode the operation information on a short-range wireless signal broadcast at a short distance without specifying a receiver according to a specified short-range wireless standard and transmit the short-range wireless signal. For example, the communication unit 235 may encode the operation information in a BLE signal after Bluetooth specification 4.0 and transmit it at a short distance.

According to an embodiment of the present invention, the communication unit 235 performs a pairing procedure with a designated wireless terminal according to a specified short-range wireless standard at least once, and the paired radio through a two-way short-range wireless communication according to the short-range wireless standard. A function of transmitting the operation information to an app of the terminal may be performed. For example, the communication unit 235 performs a pairing procedure with a wireless terminal designated according to the Bluetooth standard and transmits the operation information to an app of the paired wireless terminal through bidirectional Bluetooth communication according to the Bluetooth standard. can do.

On the other hand, according to an embodiment of the present invention, a short-range wireless standard for transmitting a short-range wireless signal or short-range wireless communication is not limited to the above-described Bluetooth, and is designated at a short distance (for example, Wi-Fi or Zig bee). It is clear that it includes all short-range wireless standards capable of transmitting radio signals within 30 m or less, and up to 100 m).

Meanwhile, when the output unit 215 is provided in the operation module 200, the output unit 215 may output the generated / stored operation information. On the other hand, when the operation information including a plurality of information is generated through the generation unit 210 and the output of the generated plurality of information through the output unit 215 is not possible, the output unit 215 is preset The information output according to the rules may be changed and output, and / or information output in response to user manipulation through the operation unit 230 may be changed and output.

3 is a view showing a manufacturing process of the stationary outlet device 100 according to an embodiment of the present invention.

In more detail, FIG. 3 shows a ferroelectric mixture produced using N (N≥2) designated materials and at least two electrode parts 145 arranged to be insulated from each other in a specified geometric relationship inside the stationary outlet device 100. The contact portion 125 provided on the side of the electrode portion 145 and the M plug inserting portion 110 in the ferroelectric mixture 140 and the AC power applied through the power plug portion 105 while having 140 are provided. By connecting in parallel, the harmonics and thermal noise of AC power applied to an electrical appliance or other stationary outlet through the contact portion 125 of the plug insertion part 110 are absorbed in parallel to simultaneously save primary power and simultaneously supply the power plug. The wall-mounted outlet receiving the AC power applied from the switchboard or distribution panel while the unit 105 is inserted into the plug-in part of the wall-mounted outlet or another stationary outlet. Other wall-types that share the AC power applied from the switchboard or distribution panel as well as secondary power saving by absorbing harmonics and heat noise of AC power applied to other electrical products in parallel through the contact part of the other plug-in part of the other outlet. As a diagram showing the manufacturing process of a stationary outlet device 100 that absorbs harmonics and heat noise of AC power applied to other electrical products in parallel through a plug insertion part of an outlet in parallel and saves tertiary energy, the present invention belongs to the technical field. If a person with ordinary skill in the art, it is possible to infer various implementation methods (for example, some steps are omitted or an order is changed) for the production process by referring to and / or modifying this drawing 3, The present invention comprises all of the above-described inferred implementation methods, and the implementation shown in FIG. 3 The technical characteristics of the method are not limited.

Referring to FIG. 3, in order to prepare the ferroelectric mixture 140, a raw material containing N designated substances in a specified weight percentage (wt (%)) range is prepared (300), and the prepared raw material is mixed and crushed through a grinder. While stirring to produce a mixed powder (305).

According to the first mixture preparation example of the present invention, after preparing the raw materials prepared for each N designated materials to prepare a mixed powder (300), the prepared raw materials for each material at a mixing ratio corresponding to the specified weight percentage range By mixing and pulverizing through a grinder to a size of 100 mesh to 200 mesh, it is possible to generate a mixed powder by stirring (305).

According to the second mixture preparation example of the present invention, after preparing n (1 ≤ n ≤ N) ore raw materials containing N designated substances to prepare a mixed powder (300), included in each of the ore raw materials Based on the weight percentage of each material, the prepared ore raw materials can be mixed at a mixing ratio corresponding to a specified weight percentage range and stirred while crushing to a size of 100 mesh to 200 mesh through a grinder to generate a mixed powder (305). .

According to a third embodiment of the present invention, in order to prepare a mixed powder, i (1≤i≤N) ore raw materials including at least some of N designated materials are prepared and among the N designated materials Even if it is not included in the i ore raw materials or included in the i ore raw materials, after preparing raw materials for each of j (1≤j≤N, N = i∪j) materials that are insufficient to match the specified weight percentage range (300 ), based on the weight percentage of each ore contained in i ore raw materials, the prepared i ore raw materials and j raw materials for each material are mixed at a mixing ratio corresponding to a specified weight percentage range to a size of 100 mesh to 200 mesh through a grinder. It can be stirred while grinding to produce a mixed powder (305).

According to a fourth mixture preparation embodiment of the present invention, k (1≤k≤N) waste raw materials (for example, used in solar power generation) containing at least some of N designated materials to produce a mixed powder After preparing (300) the waste sludge of the photovoltaic panel generated in the process of manufacturing the photovoltaic panel, the waste sludge of the photovoltaic panel used for photovoltaic power generation, or the ferroelectric mixture (140, etc.) that failed quality inspection (300), Based on the weight percentage of each material contained in the k waste raw materials, the prepared k waste raw materials are mixed at a mixing ratio corresponding to a specified weight percentage range and pulverized to a size of 100 mesh to 200 mesh through a grinder and stirred to generate a mixed powder. It can be done (305).

According to a fifth embodiment of the present invention, p (1≤p≤N) waste raw materials (for example, used in solar power generation) including at least some of N designated materials to produce a mixed powder Prepare the waste sludge of the photovoltaic panel generated during the manufacturing process of the photovoltaic panel, or the waste sludge of the photovoltaic panel used for photovoltaic power generation or waste, or the ferroelectric mixture 140 that has failed quality inspection, etc. After preparing the raw materials for each q (1≤q≤N, N = p∪q) material that does not match the specified weight percentage range even if they are not included in the p waste raw materials or included in the p waste raw materials, (300), based on the weight percentage of each material contained in p waste raw materials, the prepared p waste raw materials and q raw materials for each material correspond to a specified weight percentage range By mixing at a combined ratio and stirring while crushing to a size of 100 mesh to 200 mesh through a grinder, a mixed powder may be generated (305).

According to the sixth mixture preparation example of the present invention, s (1 ≤ s ≤ N) ore raw materials and t (1 ≤ t ≤ N) containing at least some of the N specified substances to produce a mixed powder Prepare the raw materials for the four waste materials and do not match the specified weight percentage range even if they are not included in the s ore materials and t waste materials among the N designated materials or in the s ore materials and t waste materials. After preparing the raw materials for each of the insufficient u (1≤u≤N, N = s∪t∪u) materials (300), the prepared s based on the weight percentage for each of the s ore materials and t waste materials Mix ore materials and t waste raw materials and raw materials for each u material at a mixing ratio corresponding to a specified weight percentage range, and mix through a grinder to a size of 100 mesh to 200 mesh while stirring to generate a mixed powder. Is 305.

When the mixed powder is generated, the mixed powder is introduced into a low-temperature drying furnace, oxidized while supplying oxygen through dried air, and then cooled through nitrogen (N2) to produce a stabilized oxidation mixture in air (310). Preferably, it is preferable to oxidize the mixed powder for at least 45 hours through dried air at 80 ° C (ㅁ 10 ° C) in a low-temperature drying furnace to generate an oxidation mixture.

When the oxidizing mixture is produced, the oxidizing mixture is calcined at a temperature of 890 ° C to 970 ° C for 10 hours or more in an electric furnace and cooled through nitrogen (N2) to generate a calcined mixture (315).

When the calcined mixture is produced, a liquid mixture is generated by mixing the designated binder and the calcined mixture at a preset mixing ratio to liquefy (320).

In order to fabricate the ferroelectric mixture 140 having a specified geometry, at least two electrode parts 145 made of a high-conductivity metal material are arranged and fixed in a specified geometry relationship to be insulated from each other in a frame made of the specified geometry. It is provided with a connection contact for electrical connection with the designated connection portion 155 on one side of the (145), the ferroelectric mixture 140 is mounted in the designated mounting space formed in the body portion 160 of the outlet device 100 To prepare a manufacturing frame including an inner space for forming a fixed geometry structure (325).

When the production frame is prepared, the liquid mixture is poured into the production frame and the liquid mixture is in close contact with the electrode portion 145 disposed in a specified geometric relationship while being dried at room temperature, and the designated geometry structure corresponding to the frame is dried. And solidify to (330).

If the liquid mixture is solidified and the ferroelectric mixture 140 is formed, the solidified ferroelectric mixture 140 is separated from the fabrication frame (335), and then a designated quality inspection for the ferroelectric mixture 140 (eg, Insulation tests (non-breakthrough tests, etc.) between the electrode parts 145 disposed to be mutually insulated are performed (340).

If the quality inspection of the ferroelectric mixture 140 fails, the ferroelectric mixture 140 that fails the quality inspection is discarded (345), and the discarded ferroelectric mixture 140 is used again as a raw material for the mixed powder.

On the other hand, if the quality inspection of the ferroelectric mixture 140 is successful, the M plug insertion unit while mounting or fixing the ferroelectric mixture 140 in a mounting space formed inside the body portion 160 of the outlet device 100 (110) The M first contact portion 125 provided in the first terminal insertion hole 115 of each side and one terminal of the power plug portion 105 are electrically connected to the M first contact portions ( 125) is a first electrode designated among the electrode portions 145 provided in the ferroelectric mixture 140, the first connection portion 155 electrically connected to the first wiring portion 130 forming the wiring for applying AC power. At the same time as being electrically connected to the connection contact provided in the part 145, the M second contact parts 125 provided in the second terminal insertion hole 115 on the other side of each of the M plug insertion parts 110 And the other terminal of the power plug 105 by electrically connecting An electrode unit provided in the ferroelectric mixture 140 has a second connection unit 155 electrically connected to the second wiring unit 130 forming a wiring for applying AC power to the M second contact units 125 ( 145) of the first electrode part 145 and formed a specified geometrical relationship, electrically connected to a connection contact provided in the second electrode part 145 arranged to be insulated, and equipped with an operating module 200 to mount the outlet device. Produce (100) (350).

100: stationary outlet device 105: power plug
110: plug insertion section 115: terminal insertion hole
120: grounding portion 125: contact portion
130: wiring section 135: grounding section
140: ferroelectric mixture 145: electrode portion
150: switch unit 155: connection unit
160: body 200: operating module
205: sensor unit 210: generation unit
215: output unit 220: power supply unit
225: storage unit 230: operation unit
235: Communication Department

Claims (31)

A stationary outlet device having a power plug unit for receiving AC power and M (M≥1) plug insertion units for supplying AC power, and at least two terminal insertion holes of a structure specified at a designated position of the plug insertion unit are formed. ,
N (N≥2) designated substances containing silicon (Si) and aluminum (Al) in a specified weight percentage (wt (%)) range are mixed at a predetermined mixing ratio and pulverized while mixing and stirring the mixed powder in a low-temperature drying furnace. After oxidizing to produce an oxidizing mixture, calcined at a predetermined temperature in an electric furnace, cooled, and then liquefied by mixing the resulting calcined mixture with a predetermined binder and a predetermined blending ratio, and at least two electrode parts arranged to be insulated from each other in a specified geometric relationship A ferroelectric mixture produced by solidifying the liquefied mixture in a liquid phase followed by drying and then solidifying it into a specified geometry;
Wiring for applying AC power to the M first contacts by electrically connecting the M first contacts provided in the first terminal insertion hole of each side of the M plug inserts and one terminal of the power plug part. A first wiring unit forming a;
Applying AC power to the M second contact portions by electrically connecting the M second contact portions provided in the second terminal insertion hole on the other side of each of the M plug insertion portions and the other side terminal of the power plug portion. A second wiring unit forming a wiring for the;
A first connection portion electrically connecting the first contact portion and a connection contact provided at a designated first electrode portion of the electrode portions provided in the ferroelectric mixture;
A second connection part electrically connecting the second wiring part with a connection contact provided in the second electrode part which is insulated by forming a specified geometrical relationship with the first electrode part among the electrode parts provided in the ferroelectric mixture;
A sensor unit that senses a designated sensing value including an amount of power used for power saving through the ferroelectric mixture in conjunction with at least one of the wiring unit and the connection unit;
A generating unit generating operation information designated through the sensed sensing value; And
Communication unit for transmitting the short-range wireless signal containing the operation information or transmitting the operation information to the app of the designated wireless terminal through the specified short-range wireless communication; and a short-range wireless communication function including and a power saving function using a ferroelectric connected in parallel Stationary outlet device.
The method of claim 1, wherein the specified weight percentage range,
Silicon (Si) in the range of 10-40 wt (%),
A stationary outlet device having a short-range wireless communication function and a power saving function using a parallel-connected ferroelectric, comprising aluminum (Al) in a range of 10 to 40 wt (%).
According to claim 2, The sum of the weight percentage of the silicon (Si) and aluminum (Al),
A stationary outlet device equipped with a short-range wireless communication function characterized by being within 60 (+5) wt (%) and a power saving function using a ferroelectric connected in parallel.
The method of claim 2, wherein the N designated substances,
Iron (Fe) in the range of 5-20 wt (%),
A stationary outlet device having a short-range wireless communication function and a power saving function using a ferroelectric connected in parallel, characterized in that it further comprises at least one material of magnesium (Mg) in a range of 5 to 20 wt (%).
The method according to claim 2 or 4, wherein the N designated substances are:
Zirconium (Zr) within 5wt (%),
Sodium (Na) within 5wt (%),
Potassium (K) within 5wt (%),
Calcium (Ca) within 5wt (%),
Titanium (Ti) within 5wt (%),
Zirconium boride (ZrB2) within 5wt (%),
Titanium compound (TiB2) within 5wt (%),
A stationary outlet device having a short-range wireless communication function and a power saving function using a ferroelectric connected in parallel, characterized in that it further comprises at least one material of titanium barium (BaTi) within 5 wt (%).
According to claim 1, The mixed powder,
After preparing raw materials prepared for N designated substances,
A stationary outlet device having a short-range wireless communication function and a power saving function using a parallel-connected ferroelectric, characterized in that the prepared raw materials for each material are generated by mixing and mixing at a mixing ratio corresponding to a specified weight percentage range, and stirring.
According to claim 1, The mixed powder,
After preparing n (1≤n≤N) ore raw materials containing N designated materials,
A stationary outlet device having a short-range wireless communication function and a power saving function using a parallel-connected ferroelectric, characterized in that the prepared n ore raw materials are generated by mixing and stirring at a mixing ratio corresponding to a specified weight percentage range.
According to claim 1, The mixed powder,
Prepare i (1≤i≤N) ore raw materials containing at least some of the N specified materials, and j (1≤j≤N, N not included in the i ore raw materials or insufficient in a specified weight percentage range = i∪j) After preparing raw materials for each substance,
The prepared i ore raw material and j raw material for each material are produced by mixing and pulverizing and mixing corresponding to a specified weight percentage range, and a stationary outlet device having a short-range wireless communication function and a power saving function using a parallel-connected ferroelectric material is generated. .
According to claim 1, The mixed powder,
After preparing k (1≤k≤N) waste raw materials containing N designated substances,
A stationary outlet device having a short-range wireless communication function and a power saving function using a parallel-connected ferroelectric, characterized in that the prepared k waste materials are generated by mixing and stirring at a mixing ratio corresponding to a specified weight percentage range.
According to claim 1, The mixed powder,
Prepare p (1≤p≤N) waste raw materials containing at least some of the N designated substances, and q (1≤q≤N, N not included in the p waste raw materials or insufficient in a specified weight percentage range = p∪q) After preparing raw materials for each material,
A stationary outlet device having a short-range wireless communication function and a power saving function using a parallel-connected ferroelectric, characterized in that the prepared p waste materials and q materials are generated by mixing and crushing corresponding to a specified weight percentage range. .
According to claim 1, The mixed powder,
S (1 ≤ s ≤ N) ore raw materials and t (1 ≤ t ≤ N) waste raw materials including at least some of the N designated substances are prepared, and the s ore substances and t waste raw materials are prepared. After preparing raw materials for u (1≤u≤N, N = s∪t∪u) substances that are not included in or insufficient for the specified weight percentage range,
A short-range wireless communication function and a power saving function using a parallel-connected ferroelectric are produced by mixing and smashing the prepared s ore materials, t waste raw materials, and u raw materials for each material by mixing and grinding corresponding to a specified weight percentage range. Equipped with a wall outlet device.
The method of claim 9 or claim 10 or claim 11, wherein the raw material for waste,
Waste sludge of solar panel,
A stationary outlet device having a short-range wireless communication function and a power saving function using a parallel-connected ferroelectric, characterized in that it comprises at least one raw material of a ferroelectric mixture that has failed quality inspection.
According to claim 1, The mixed powder,
A stationary outlet device equipped with a short-range wireless communication function and a power saving function using a parallel-connected ferroelectric, characterized in that it is generated by pulverizing the mixed raw materials to a size of 100 mesh to 200 mesh to correspond to a specified weight percentage range.
The method of claim 1, wherein the oxidation mixture,
A stationary outlet device having a short-range wireless communication function and a power saving function using a parallel-connected ferroelectric, characterized in that it is produced by oxidizing the mixed powder for at least 45 hours through dry air at 80 ° C (ㅁ 10 ° C) in a low-temperature drying furnace.
According to claim 1, The calcined mixture,
A stationary outlet device having a short-range wireless communication function and a power saving function using a parallel-connected ferroelectric, characterized in that it is generated by firing the oxidation mixture at a temperature of 890 ° C to 970 ° C for 10 hours or more in an electric furnace.
The method of claim 1, wherein the binder,
A stationary outlet device having a short-range wireless communication function and a power saving function using a ferroelectric connected in parallel, characterized by comprising an inorganic compound that liquefies by combining mineral powder.
According to claim 1, The blending ratio,
A stationary outlet device having a short-range wireless communication function and a power saving function using a ferroelectric connected in parallel, characterized in that the ratio of the binder to the calcined mixture is within 10%.
The geometrical relationship of claim 1,
In order to maximize the generation of electric polarization (or dielectric polarization) between the mutually insulated electrode parts, the short-distance wireless communication function and parallel, characterized in that it comprises a relationship in which each electrode part is spaced apart from each other in a distance relationship of 1 cm to 1.5 cm. Stationary outlet device with power saving function using a connected ferroelectric.
The geometrical relationship of claim 1,
A stationary outlet device having a short-range wireless communication function and a power saving function using a parallel-connected ferroelectric, characterized in that it comprises a relationship in which two designated electrode parts insulated from each other are arranged in parallel.
The geometrical relationship of claim 1,
A stationary outlet device having a short-range wireless communication function and a power saving function using a parallel-connected ferroelectric, characterized in that it comprises a relationship between two mutually insulated designated two electrode parts.
The geometrical relationship of claim 1,
A stationary outlet device having a short-range wireless communication function and a power saving function using a ferroelectric connected in parallel, characterized in that it comprises a relationship in which two designated electrode parts that are mutually insulated are arranged in a hierarchical structure.
The geometrical relationship of claim 1,
A short-range wireless communication function and a parallel connection type ferroelectric, comprising a relationship in which a vertical distance between the surface of each electrode part provided inside the ferroelectric mixture and the outer surface of the ferroelectric mixture is arranged to be spaced apart by at least 0.5 cm or more. Stationary outlet device with power saving function.
According to claim 1, The electrode portion,
A stationary outlet device having a short-range wireless communication function and a power saving function using a parallel-connected ferroelectric, characterized in that it comprises an electrode plate having a length of 3 cm or more, a width of 0.5 cm or more, and a thickness of 0.1 cm or more for each electrode part.
According to claim 1, The electrode portion,
A stationary outlet device having a short-range wireless communication function and a power saving function using a parallel-connected ferroelectric, characterized in that an area of at least 3.6 cm 2 or more for each electrode portion includes a contact area in contact with the ferroelectric mixture.
The method of claim 1, wherein the ferroelectric mixture,
A stationary outlet device having a short-range wireless communication function and a power saving function using a parallel-connected ferroelectric, comprising at least 45 cm 3 or more in volume.
According to claim 1, The electrode portion,
Short-range wireless communication characterized in that the insulation resistance between the two electrode parts is measured at least 100 MΩ or infinitely in a state where a voltage of 1000 V (ㅁ 100 V) is applied to two electrode parts arranged to be insulated from each other in a specified geometric relationship. Stationary outlet device with power saving function using a function and a parallel-connected ferroelectric.
According to claim 1,
A stationary outlet having a short-range wireless communication function and a power saving function using a parallel-connected ferroelectric, further comprising a storage unit for storing setting information for generating designated operation information using the sensed value sensed through the sensor unit. Device.
The method of claim 27,
The sensor unit includes a sensor for sensing the amount of power used for power saving through the ferroelectric mixture,
The setting information includes period information for calculating a cumulative amount of power used during a certain period of time through the ferroelectric mixture based on a sensed value sensed through the sensor unit, or information on the initialization of the accumulated amount of power. Stationary outlet device with short-range wireless communication function and power saving function using a ferroelectric connected in parallel.
The operating information according to claim 1 or 27,
Electricity information used for power saving through the ferroelectric mixture, and
A stationary outlet device having a short-range wireless communication function and a power saving function using a parallel-connected ferroelectric, characterized in that it comprises at least one of cumulative power consumption information used for power saving for a period of time through the ferroelectric mixture.
The method of claim 1, wherein the short-range wireless signal,
A stationary outlet device having a short-range wireless communication function and a power saving function using a parallel-connected ferroelectric, characterized in that it comprises a wireless signal broadcast at a short distance without specifying a receiver according to a specified short-range wireless standard.
According to claim 1, The communication unit,
And performing a procedure of pairing with a designated wireless terminal at least once according to a specified short-range wireless standard and transmitting the operation information to an app of the paired wireless terminal through the short-range wireless communication. Stationary outlet device with communication function and power saving function using a parallel-connected ferroelectric.

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