KR102853187B1 - Stationary type Electrical Outlet Device equipped with Short-range Wireless Communication Function and Intuitive Power Saving Functionby using Straightway type Oxide Mixture - Google Patents

Abstract

The present invention relates to a stationary outlet device having an intuitive power-saving function using a serial oxide mixture, and is provided with a power plug for receiving AC power and M (M≥1) plug insertion portions for supplying AC power, and two terminal insertion holes of a designated structure are formed at designated positions of the plug insertion portions, wherein a mixture including oxides in a mixed powder form, which is obtained by mixing N (N≥2) designated substances including silicon (Si) and aluminum (Al) in a designated weight percentage (wt(%)) range at a predetermined mixing ratio and stirring while grinding, is mixed with a designated binder at a predetermined mixing ratio and liquefied, and then an electrically conductive first electrode portion and a second electrode portion are mutually insulated in a designated geometric relationship, and the liquefied liquid mixture is injected into a frame having a geometric structure that can be installed inside the body of the outlet device, and the liquid mixture is solidified while drying in a state where the first electrode portion and the second electrode portion are in liquid contact without any voids, so that the stationary outlet device has dielectric properties, thermal conductivity, and electrical insulation corresponding to the oxide, and the closely contacted first electrode portion and An oxide mixture that removes a designated resistance component on an electric line electrically connected to a second electrode section in the form of heat energy, a first conducting portion that electrically connects a power contact provided in a first electrode section of the oxide mixture and one terminal of the power plug section, a second conducting portion that electrically connects a power contact provided in a second electrode section that is insulated by forming a designated geometric relationship with the first electrode section of the oxide mixture and the other terminal of the power plug section, a first wiring portion that forms a wiring that electrically connects a designated wiring contact of the first electrode section of the oxide mixture and M first contacts provided in first terminal insertion holes on one side of each of the M plug insertion sections, a second wiring portion that forms a wiring that electrically connects a designated wiring contact of the second electrode section of the oxide mixture and M second contacts provided in second terminal insertion holes on the other side of each of the M plug insertion sections, and a second wiring portion that electrically connects the first conducting portion and the first wiring portion to the first electrode section of the oxide mixture and maintains an electrical connection state in which the second conducting portion and the second wiring portion are electrically connected to the second electrode section of the oxide mixture, or the electrical connection A processing unit that temporarily releases the state and switches to a direct power application state in which power can be directly applied from the first conductor part and the second conductor part to the first wiring part and the second wiring part, and then processes the electrical connection state to be restored, a sensor unit that is electrically connected to the first wiring part and the second wiring part and senses a power-saving sensing value corresponding to the amount of power applied and used through the first electrode part and the second electrode part of the oxide mixture when the electrical connection state is maintained through the processing unit, and senses a non-power-saving sensing value corresponding to the amount of power directly applied and used to the first wiring part and the second wiring part in an electrically insulated state from the first electrode part and the second electrode part of the oxide mixture when the electrical connection state is temporarily released, a generating unit that generates designated processing information using at least one of the sensed power-saving sensing value and the non-power-saving sensing value, and a communication unit that transmits a short-range wireless signal including the processing information or transmits the processing information to an app of a designated wireless terminal through a designated short-range wireless communication, wherein the oxide mixture is connected to the power plug part through the first electrode part and the second electrode part within the body of the outlet device. It provides double power saving by removing in parallel the resistance component on the external electric line including the electric line connected to the power plug section in the designated distribution board or branch board by connecting in parallel with the side, and simultaneously removing in series the resistance component generated by the electric device that connects the internal electric line through each plug insertion section by connecting in series with each plug insertion section.

Description

Stationary type electrical outlet device equipped with short-range wireless communication function and intuitive power saving function by using straightway type oxide mixture

The present invention relates to a stationary outlet device having a power plug for receiving AC power and M (M≥1) plug insertion portions for supplying AC power, and two terminal insertion holes of a designated structure formed at designated positions of the plug insertion portions, the method comprising: mixing N (N≥2) designated substances including silicon (Si) and aluminum (Al) in a designated weight percentage (wt(%)) range at a predetermined mixing ratio, grinding, and stirring a mixture of oxides in a mixed powder form, mixing the mixture with a designated binder at a predetermined mixing ratio, liquefying it, and then placing an electrically conductive first electrode portion and a second electrode portion in a designated geometric relationship so as to be mutually insulated, and then injecting the liquefied liquid mixture into a frame having a geometric structure that can be installed inside the body of the outlet device, and solidifying the liquid mixture while drying it in a state where the first electrode portion and the second electrode portion are in liquid contact without any voids, thereby manufacturing the oxide to have dielectric properties, thermal conductivity, and electrical insulation properties corresponding to the oxide, thereby removing a designated resistance component on an electric line electrically connected to the first electrode portion and the second electrode portion in the form of heat energy. A first conductor part electrically connecting a power contact provided in a first electrode part of the mixture and the oxide mixture and one terminal of the power plug part, a second conductor part electrically connecting a power contact provided in a second electrode part insulated by forming a designated geometric relationship with the first electrode part of the oxide mixture and the other terminal of the power plug part, a first wiring part forming a wiring electrically connecting a designated wiring contact of the first electrode part of the oxide mixture and M first contacts provided in the first terminal insertion holes of one side of each of the M plug insertion parts, a second wiring part forming a wiring electrically connecting a designated wiring contact of the second electrode part of the oxide mixture and M second contacts provided in the second terminal insertion holes of the other side of each of the M plug insertion parts, and a second wiring part electrically connecting the first conductor part and the first wiring part to the first electrode part of the oxide mixture and maintaining an electrical connection state in which the second conductor part and the second wiring part are electrically connected to the second electrode part of the oxide mixture, or temporarily releasing the electrical connection state to perform the first A processing unit for switching to a direct power application state in which power can be directly applied to the wiring unit and the second wiring unit and then processing to return to the electrical connection state, a sensor unit for sensing a power-saving sensing value corresponding to the amount of power applied and used through the first electrode unit and the second electrode unit of the oxide mixture when the electrical connection state is maintained through the processing unit, and sensing a non-power-saving sensing value corresponding to the amount of power directly applied and used through the first wiring unit and the second wiring unit in a state of electrical insulation from the first electrode unit and the second electrode unit of the oxide mixture when the electrical connection state is temporarily released, a generating unit for generating designated processing information using at least one of the sensed power-saving sensing value and the non-power-saving sensing value, and a communication unit for transmitting a short-range wireless signal including the processing information or transmitting the processing information to an app of a designated wireless terminal through a designated short-range wireless communication, wherein the oxide mixture is connected in parallel to the power plug unit side through the first electrode unit and the second electrode unit within the body of the outlet device and connected to the power plug unit from a designated distribution board or a distribution board. The present invention relates to a stationary outlet device having an intuitive power-saving function using a series-type oxide mixture that provides dual power-saving by removing in parallel the resistance component on an external electric line including an electric line, and simultaneously removing in series the resistance component generated by an electric device that is connected in series with each plug insertion portion and connects an internal electric line through each plug insertion portion.

Various power outlet devices have been proposed in the past for energy conservation. However, conventional power-saving outlet devices are provided in a form that senses the power amount of an electrical device connected to the plug insertion part and blocks standby power (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 No. 10-1731266 (April 24, 2017), etc.).

However, conventional energy-saving outlet devices only block the use of standby power when the connected electrical device is turned off, and do not provide a function to save power when the electrical device is turned on. In particular, any conventional energy-saving outlet device has the problem that it does not save power at all for electrical devices other than the power used by the electrical device connected to the outlet device.

The purpose of the present invention to solve the above problems is to provide a stationary outlet device having a power plug for receiving AC power and M (M≥1) plug insertion portions for supplying AC power, and two terminal insertion holes of a designated structure formed at designated positions of the plug insertion portions, wherein a mixture including an oxide in the form of a mixed powder, which is mixed and stirred while grinding N (N≥2) designated substances including silicon (Si) and aluminum (Al) in a designated weight percentage (wt(%)) range at a predetermined mixing ratio, is mixed with a designated binder at a predetermined mixing ratio and liquefied, and then a first electrode portion and a second electrode portion are arranged in a designated geometric relationship to be insulated from each other, and the liquefied liquid mixture is injected into a frame having a geometric structure that can be installed inside the body of the outlet device, and the first electrode portion and the second electrode portion are solidified while drying the liquid mixture in a state of liquid contact without voids, so as to have dielectric properties, thermal conductivity and electrical insulation corresponding to the oxide, and an electric line electrically connected to the contacted first electrode portion and the second electrode portion. An oxide mixture that removes a specified resistance component in the form of heat energy, a first conductive part that electrically connects a power contact provided in a first electrode portion of the oxide mixture and one terminal of the power plug portion, a second conductive part that electrically connects a power contact provided in a second electrode portion that is insulated by forming a specified geometric relationship with the first electrode portion of the oxide mixture and the other terminal of the power plug portion, a first wiring part that forms a wiring that electrically connects a specified wiring contact of the first electrode portion of the oxide mixture and M first contacts provided in the first terminal insertion holes of one side of each of the M plug insertion portions, a second wiring part that forms a wiring that electrically connects a specified wiring contact of the second electrode portion of the oxide mixture and M second contacts provided in the second terminal insertion holes of the other side of each of the M plug insertion portions, and a second wiring part that electrically connects the first conductive part and the first wiring part to the first electrode portion of the oxide mixture and maintains an electrical connection state in which the second conductive part and the second wiring part are electrically connected to the second electrode portion of the oxide mixture, or temporarily releases the electrical connection state to electrically connect the first conductive part and the first wiring part to the second electrode portion of the oxide mixture. And a processing unit that switches to a direct power application state in which power can be directly applied to the first wiring unit and the second wiring unit from the second conductor unit and processes to return to the electrical connection state, a sensor unit that is electrically connected to the first wiring unit and the second wiring unit and senses a power-saving sensing value corresponding to the amount of power applied and used through the first electrode unit and the second electrode unit of the oxide mixture when the electrical connection state is maintained through the processing unit and senses a non-power-saving sensing value corresponding to the amount of power directly applied and used through the first wiring unit and the second wiring unit in an electrically insulated state from the first electrode unit and the second electrode unit of the oxide mixture when the electrical connection state is temporarily released, a generating unit that generates designated processing information using at least one of the sensed power-saving sensing value and the non-power-saving sensing value, and a communication unit that transmits a short-range wireless signal including the processing information or transmits the processing information to an app of a designated wireless terminal through a designated short-range wireless communication, wherein the oxide mixture is connected in parallel with the power plug unit side through the first electrode unit and the second electrode unit within the body of the outlet device to a designated distribution panel or The present invention provides a stationary outlet device having an intuitive power-saving function using a series-type oxide mixture that provides dual power-saving by removing in parallel the resistance component on the external electric line including the electric line connected to the power plug section in the distribution panel, and simultaneously removing in series the resistance component generated by the electric device that is connected in series to each plug insertion section and connects the internal electric line through each plug insertion section.

A stationary outlet device having an intuitive power-saving function using a serial oxide mixture according to the present invention is a stationary outlet device having a power plug for receiving AC power and M (M≥1) plug insertion portions for supplying AC power, and two terminal insertion holes of a designated structure are formed at designated positions of the plug insertion portions, wherein a mixture including oxides in the form of mixed powder, which are mixed and stirred while grinding N (N≥2) designated substances including silicon (Si) and aluminum (Al) in a designated weight percentage (wt(%)) range at a predetermined mixing ratio, is liquefied by mixing the mixture with a designated binder at a predetermined mixing ratio, and then a first electrode portion and a second electrode portion are mutually insulated in a designated geometric relationship, and the liquefied liquid mixture is injected into a frame having a geometric structure that can be installed inside the body of the outlet device, and the liquid mixture is solidified while drying in a state where the first electrode portion and the second electrode portion are in liquid contact without any voids, so that the closely contacted first electrode portion and the second electrode portion are manufactured to have dielectric properties, thermal conductivity and electrical insulation properties corresponding to the oxide. An oxide mixture that removes a designated resistance component on an electric line electrically connected to a second electrode section in the form of heat energy, a first conducting portion that electrically connects a power contact provided in a first electrode section of the oxide mixture and one terminal of the power plug section, a second conducting portion that electrically connects a power contact provided in a second electrode section that is insulated by forming a designated geometric relationship with the first electrode section of the oxide mixture and the other terminal of the power plug section, a first wiring portion that forms a wiring that electrically connects a designated wiring contact of the first electrode section of the oxide mixture and M first contacts provided in first terminal insertion holes on one side of each of the M plug insertion sections, a second wiring portion that forms a wiring that electrically connects a designated wiring contact of the second electrode section of the oxide mixture and M second contacts provided in second terminal insertion holes on the other side of each of the M plug insertion sections, and a second wiring portion that electrically connects the first conducting portion and the first wiring portion to the first electrode section of the oxide mixture and maintains an electrical connection state in which the second conducting portion and the second wiring portion are electrically connected to the second electrode section of the oxide mixture, or the electrical connection A processing unit that temporarily releases the state and switches to a direct power application state in which power can be directly applied from the first conductor part and the second conductor part to the first wiring part and the second wiring part, and then processes the electrical connection state to be restored, a sensor unit that is electrically connected to the first wiring part and the second wiring part and senses a power-saving sensing value corresponding to the amount of power applied and used through the first electrode part and the second electrode part of the oxide mixture when the electrical connection state is maintained through the processing unit, and senses a non-power-saving sensing value corresponding to the amount of power directly applied and used to the first wiring part and the second wiring part in an electrically insulated state from the first electrode part and the second electrode part of the oxide mixture when the electrical connection state is temporarily released, a generating unit that generates designated processing information using at least one of the sensed power-saving sensing value and the non-power-saving sensing value, and a communication unit that transmits a short-range wireless signal including the processing information or transmits the processing information to an app of a designated wireless terminal through a designated short-range wireless communication, wherein the oxide mixture is connected to the power plug part through the first electrode part and the second electrode part within the body of the outlet device. It is characterized by providing double power saving by removing in parallel the resistance component on the external electric line including the electric line connected to the power plug section in the designated distribution board or branch board by connecting in parallel with the side, and simultaneously removing in series the resistance component generated by the electric device that connects the internal electric line through each plug insertion section by connecting in series with each plug insertion section side.

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

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

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

According to the present invention, the mixed powder can be produced by preparing i (1 ≤ i ≤ N) ore raw materials including at least some of N designated materials, preparing j (1 ≤ j ≤ N, N = i ∪ j) material-specific raw materials that are not included in the i ore raw materials or are insufficient for a designated weight percentage range, and then mixing and grinding the prepared i ore raw materials and j material-specific raw materials corresponding to a designated weight percentage range, and stirring.

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

According to the present invention, the mixed powder can be produced by preparing p (1 ≤ p ≤ N) waste raw materials containing at least some of N designated materials, preparing q (1 ≤ q ≤ N, N = p∪q) material-specific raw materials that are not included in the p waste raw materials or are insufficient for a designated weight percentage range, and then mixing and grinding the prepared p waste raw materials and q material-specific raw materials corresponding to a designated weight percentage range, and stirring.

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

According to the present invention, the waste raw material may include at least one of waste sludge from solar panels and a mixture of oxides that have failed quality inspection.

According to the present invention, the mixed powder can be produced by stirring and grinding the mixed raw materials to a size of 100 mesh to 200 mesh so as to correspond to a specified weight percentage range.

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According to the present invention, it is preferable that the mixing ratio be such that the ratio of binder to the mixture is within 10%.

According to the present invention, the geometric relationship may include a relationship in which two mutually insulated designated electrode portions are arranged in parallel.

According to the present invention, the geometric relationship may include a relationship in which two designated electrode portions are arranged opposite each other and are mutually insulated.

According to the present invention, the geometric relationship may include a relationship in which two designated electrode portions that are mutually insulated are arranged in a hierarchical structure.

According to the present invention, each 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.

According to the present invention, the electrode portion is characterized in that each electrode portion includes a contact area in contact with the oxide mixture of at least 3.6㎠.

According to the present invention, the oxide mixture may have a volume of at least 45㎤ or more.

According to the present invention, it is preferable that the insulation resistance between the two electrode parts is measured to be at least 100 MΩ or infinite when a voltage of 1000 V (±100 V) is applied to the two electrode parts that are arranged to be mutually insulated in a specified geometric relationship.

According to the present invention, the processing unit can process the electrical connection state to be temporarily released and then restored periodically while maintaining the electrical connection state.

According to the present invention, the processing unit can check whether the amount of power used while maintaining the electrical connection state changes by more than a preset reference value, and if it changes by more than the reference value, can temporarily release the electrical connection state and then process it to be restored.

According to the present invention, the above-mentioned stand-alone outlet device may further include a storage unit that stores setting information for generating designated processing information using at least one of a power-saving sensing value and a non-power-saving sensing value sensed through the sensor unit.

According to the present invention, the setting information may include period information for calculating the accumulated power amount used for power saving over a certain period of time through the oxide mixture based on the power amount corresponding to the sensing value sensed through the sensor unit, or initialization time information of the accumulated power amount.

According to the present invention, the generation unit can generate power-saving information by subtracting the power corresponding to the power-saving sensing value sensed while the electrical connection state is maintained from the power corresponding to the non-power-saving sensing value temporarily sensed while the electrical connection state is temporarily released.

According to the present invention, the storage unit stores, in a designated storage area, a designated power-saving sensing value including an amount of power continuously sensed through the sensor unit while the electrical connection state is maintained and a designated non-power-saving sensing value including an amount of power temporarily sensed through the sensor unit while the electrical connection state is temporarily released, in a time-series manner, and the generation unit calculates cumulative power information used for power-saving for a designated period of time through the oxide mixture based on the amount of power corresponding to the power-saving sensing value sensed while the electrical connection state is maintained, and calculates estimated non-power-saving cumulative power information in the case where power-saving was not performed through the oxide mixture for a designated period of time based on the relationship between the stored power-saving sensing value and the non-power-saving sensing value, and generates saved cumulative power information by subtracting the power-saving cumulative power information from the calculated non-power-saving cumulative power information.

According to the present invention, the short-range wireless signal may include a wireless signal that is broadcast in a short range without specifying a receiving end according to a designated short-range wireless standard.

According to the present invention, the communication unit may include a function of performing a pairing procedure with a designated wireless terminal at least once according to a designated short-range wireless standard and transmitting the processing information to an app of the paired wireless terminal through the short-range wireless communication.

According to the present invention, harmonics and thermal noise of AC power supplied to an electrical appliance connected to a wall-mounted outlet or another wall-mounted outlet are absorbed in series through an oxide mixture, thereby reducing the resistance component on a line supplying the AC power and rapidly increasing the movement speed of free electrons flowing in the conductor, thereby having the advantage of directly saving power being used while the AC power is being used using the wall-mounted outlet.

According to the present invention, while conventional power saving is achieved by simply blocking standby power, by maintaining a stationary outlet device connected to a conductor by having an oxide mixture and connected to a wire in a state of being connected to an AC power line supplied from a distribution board or a distribution panel (for example, without blocking the standby power of the outlet device), not only when AC power is supplied to an electrical appliance connected to a stationary outlet or another stationary outlet but also when standby power is not supplied, the stationary outlet device is connected to the conductor by having an oxide mixture, thereby absorbing in parallel harmonics and thermal noise of AC power supplied to other electrical appliances through the contact portions of other plug insertions of the wall-type outlet or other stationary outlets that share AC power supplied from the distribution board or distribution panel, thereby indirectly saving power for a second time, but also absorbing in parallel harmonics and thermal noise of AC power supplied to other electrical appliances through the contact portions of the plug insertions of other wall-type outlets that share AC power supplied from the distribution board or distribution panel, thereby indirectly saving power for a third time.

According to the present invention, there is an advantage in that, while using power using a stationary outlet, the amount of power used or the accumulated power amount saved through the oxide mixture provided in the stationary outlet is output or provided to a wireless terminal through a short-range wireless signal or short-range wireless communication, as well as the amount of power saved or the accumulated power amount through the oxide mixture.

Figure 1 is a drawing showing the configuration of a stand-alone outlet device according to the method of implementing the present invention.
Figure 2 is a block diagram illustrating the functional configuration of an operating module according to an implementation method of the present invention.
Figure 3 is a drawing illustrating a manufacturing process of a stand-alone outlet device according to an embodiment of the present invention.

The operating principles of preferred embodiments of the present invention will be described in detail with reference to the attached drawings and descriptions below. However, the drawings and descriptions below are intended to illustrate preferred implementation methods among various methods for effectively explaining the features of the present invention, and the present invention is not limited to the drawings and descriptions below.

That is, the following embodiments correspond to embodiments in the form of a preferable union among numerous embodiments of the present invention, and it is clearly stated that embodiments in which a specific configuration is omitted in the following embodiments, embodiments in which a function implemented in a specific configuration is divided into a specific configuration, embodiments in which a function implemented in two or more configurations is integrated into a single configuration, embodiments in which the operation order of a specific configuration is swapped, etc., all fall within the scope of the present invention even if not separately mentioned in the following embodiments. Therefore, it is clearly stated that various embodiments corresponding to subsets or complements based on the following embodiments can be divided retroactively to the filing date of the present invention.

Furthermore, in the following description of the present invention, detailed descriptions of known functions or configurations will be omitted if they are deemed to unnecessarily obscure the gist of the present invention. Furthermore, the terms described below are defined based on their functions within the present invention and may vary depending on the intent or custom of the user or operator. Therefore, their definitions should be based on the overall content of the present invention.

Consequently, the technical idea of the present invention is determined by the claims, and the following examples are merely a means of efficiently explaining the technical idea of the present invention to a person having ordinary skill in the art to which the present invention pertains.

Drawing 1 is a drawing showing the configuration of a stand-alone outlet device (100) according to the method of implementing the present invention.

In more detail, the drawing 1 shows a stationary outlet device (100) having a power plug portion (105) that is inserted into a plug insertion portion of a wall-mounted outlet or other stationary outlet and receives AC power supplied from a distribution board or a distribution panel, and M (M≥1) plug insertion portions (110) into which power plugs of electrical appliances or other outlets can be inserted, and an oxide mixture (140) manufactured using N (N≥2) designated materials and first electrode portions (145) and second electrode portions (145) that are mutually insulated from each other in a designated geometric relationship, while the AC power supplied through the power plug portion (105) and the contact portions (125) provided on the side of the M plug insertion portions (110) are connected in series, thereby reducing the harmonics of the AC power supplied to the electrical appliance or other stationary outlet through the contact portions (125) of the plug insertion portion (110). The present invention relates to a concept diagram of a stationary outlet device (100) that directly saves power by absorbing thermal noise in series and simultaneously indirectly saves power by absorbing in parallel the harmonics and thermal noise of AC power supplied to other electrical appliances through the contact portion of the plug insertion portion of another wall-type outlet that shares AC power supplied from the distribution board or distribution panel while the power plug portion (105) is inserted into the plug insertion portion of the wall-type outlet or other stationary outlet, and also indirectly saves power by absorbing in parallel the harmonics and thermal noise of AC power supplied to other electrical appliances through the contact portion of the plug insertion portion of another wall-type outlet that shares AC power supplied from the distribution board or distribution panel. A person having ordinary skill in the art to which the present invention pertains may infer various implementation methods (for example, implementation methods in which some components are omitted, subdivided, or combined) for the configuration of the stationary outlet device (100) by referring to and/or modifying the drawing 1. However, the present invention is implemented by including all of the above-described implementation methods, and its technical features are not limited to the implementation methods illustrated in Drawing 1. Meanwhile, for convenience, Drawing 1 illustrates an outlet device (100) having two plug insertion portions (110) to explain the features of the present invention, but the present invention is not limited thereto, and the plug insertion portions (110) of the outlet device (100) can be implemented in various ways from 1 to 6, and it is clearly stated that more than 6 embodiments are possible in some cases.

The stationary outlet device (100) of the present invention comprises a power plug portion (105) that receives AC power supplied from a distribution board or a distribution panel by being inserted into a plug insertion portion of a wall-mounted outlet or other stationary outlet, and M (M≥1) plug insertion portions (110) into which power plugs of electrical appliances or other outlets can be inserted. The power plug portion (105) is formed with two terminals having a designated structure at designated locations, and the plug insertion portion (110) is also formed with two terminal insertion holes (115) having a designated structure at designated locations. The positions and shapes of the terminals of the power plug portion (105) and the terminal insertion holes (115) of the plug insertion portion (110) have structures that match each other. Meanwhile, the power plug portion (105) may be formed with at least one grounding contact having a designated structure at a designated location. The plug insertion portion (110) may also be formed with at least one grounding portion (120) having a designated structure at a designated location. Preferably, the structure of the power plug portion (105) and the plug insertion portion (110) has a structure corresponding to one of the 14 types of electric plugs according to the International Electrotechnical Commission (IEC), and the present invention is not limited by the type of electric plug. For example, in the case of the Republic of Korea, Type C and Type F of the 14 types of electric plugs according to the International Electrotechnical Commission are applied. For convenience, the drawing 1 is illustrated based on Type F of the electric plug types of the International Electrotechnical Commission.

The above power plug part (105) is inserted into the plug insertion part of a wall-type outlet electrically connected to a distribution board or a branch board of an indoor, commercial, or industrial facility, or into the plug insertion part of another standing outlet, and thereby the terminal of the power plug part (105) is electrically connected to a contact part in a terminal insertion hole provided in the plug insertion part of the wall-type outlet or the plug insertion part of another standing outlet, and receives AC power applied from the distribution board or branch board. Meanwhile, depending on the implementation method, the power plug part (105) may further include a grounding contact or terminal for electrically connecting to a grounding part provided in the plug insertion part of a wall-type outlet electrically connected to a distribution board or a branch board, or a plug insertion part of another standing outlet, and thus for grounding. Preferably, the structure of the power plug part (105) or the position or structure of the terminal follows any one type of electric plug type according to the International Electrotechnical Commission, and the present invention is not limited thereby.

The above plug insertion part (110) can insert power plugs of various electrical products or other outlets installed in indoor, commercial or industrial facilities, and is provided with two terminal insertion holes (115) in designated positions and with designated structures, into which terminals provided in the inserted power plug can be inserted when the power plug of the electrical product or other outlet is inserted. Meanwhile, depending on the implementation method, the plug insertion part (110) may further include a grounding part (120) and a grounding line part (135) for electrically connecting to the grounding contact provided in the inserted power plug and grounding. Preferably, the structure of the plug insertion part (110) or the position or structure of the terminal insertion hole (115) follow any one of the types of electrical plugs according to the International Electrotechnical Commission, and the present invention is not limited thereby.

Referring to Drawing 1, the above-mentioned stand-alone outlet device (100) comprises: an oxide mixture (140) manufactured by mixing N (N≥2) designated substances including silicon (Si) and aluminum (Al) in a designated weight percentage (wt(%)) range at a predetermined mixing ratio, grinding, stirring, and oxidizing the mixed powder in a low-temperature drying furnace to produce an oxide mixture; then firing the resulting sintered mixture at a predetermined temperature in an electric furnace and cooling it; mixing the sintered mixture with a designated binder at a predetermined mixing ratio to liquefy it; and then drying the liquefied mixture after liquid contact with a first electrode portion (145) and a second electrode portion (145) that are mutually insulated in a designated geometric relationship, and solidifying it into a designated geometric structure; a first conductor portion (155) for electrically connecting a power contact provided in the first electrode portion (145) of the oxide mixture (140) and one side power terminal of the power plug portion (105); and a first conductor portion (155) of the oxide mixture (140). A second conductor part (155) that electrically connects the power contact provided in the second electrode part (145) that is arranged to be insulated by forming a designated geometric relationship with the electrode part (145) and the power terminal on the other side of the power plug part (105), a first wiring part (130) that forms a wiring that electrically connects the designated wiring contact of the first electrode part (145) provided in the oxide mixture (140) and the M first contact parts (125) provided in the first terminal insertion holes (115) on one side of each of the M plug insertion parts (110), a second wiring part (130) that forms a wiring that electrically connects the designated wiring contact of the second electrode part (145) provided in the oxide mixture (140) and the M second contact parts (125) provided in the second terminal insertion holes (115) on the other side of each of the M plug insertion parts (110), and the oxide mixture (140) The first electrode portion (145) and the first wiring portion (130) are electrically connected to the first electrode portion (145) and the second electrode portion (155) and the second wiring portion (130) are electrically connected to the second electrode portion (145) of the oxide mixture (140) and the electrical connection state is maintained or the electrical connection state is temporarily released so that the first electrode portion (145) and the second electrode portion (145) of the oxide mixture (140) are electrically insulated from the first conducting portion (155) and the second conducting portion (155) and the first wiring portion (130) and the second wiring portion (130), and then the electrical connection state is switched to a direct power supply state in which power can be directly supplied from the first conducting portion (155) and the second conducting portion (155) to the first wiring portion (130) and the second wiring portion (130), and then the electrical connection state is restored. When maintained, the first electrode portion (145) and the second electrode portion (145) of the oxide mixture (140) are applied to the first wiring portion (130) and the second wiring portion (130) and are used, and when the electrical connection state is temporarily released, the designated non-power-saving sensing value is sensed, including the amount of power used (hereinafter referred to as "power-saving used power"), and when the electrical connection state is temporarily released, the designated non-power-saving sensing value is sensed, and then the operating module (200) is used to generate designated processing information by using at least one of the sensed power-saving sensing value and the non-power-saving sensing value, and encode and transmit the information into a designated short-range wireless signal or transmit the information to an app of a designated wireless terminal through a designated short-range wireless communication, and the outlet (100) is provided in a designated mounting space where the oxide mixture (140), the conductor portion (155), the wiring portion (130), and the operating module (200) can be mounted, and has an outer shape corresponding to that of the outlet device (100) having M plug insertion portions (110). It includes a body part (160) that implements a structure. Meanwhile, the mounting space includes a space structure in which the oxide mixture (140) or the operating module (200) can be mounted, and the body part (160) can be manufactured as an outlet structure that further includes a space structure of the mounting space in an outlet structure having M plug insertion parts (110).

The above oxide mixture (140) is a general term for a composition that is solidified into a designated geometric structure through N (N≥2) designated substances included in a designated weight percentage (wt(%)) range and a first electrode portion (145) and a second electrode portion (145) that are mutually insulated from each other in a designated geometric relationship, and performs the function of absorbing harmonics generated from a power system or a load device (e.g., a motor) during the application or use of AC power and transmitted to each electrode portion (145), converting them into thermal energy and releasing them, thereby reducing the resistance component of the line due to the harmonics and rapidly increasing the movement speed of free electrons flowing in the wire, thereby saving power. At the same time, the composition absorbs thermal noise generated from a load device or a wire during the use of the AC power and transmitted to each electrode portion (145), converts them into thermal energy and releases them, thereby reducing the effective power amount of the load device or wire, thereby saving power.

The above harmonics are a general term for waves that make up a periodic repetitive waveform other than the fundamental wave of AC power. The periodic repetitive waveform is decomposed into waves with frequencies that are integer multiples of the fundamental wave, and the wave whose frequency is t (t ≥ 2) times the fundamental wave is called the tth harmonic. Meanwhile, in the case of AC power, harmonics are inevitably generated when converting AC voltage through a transformer, operating motors installed in various electrical products, or generating electrical signals with a frequency in various electronic products. The harmonics generated in this way propagate along the line that supplies AC power, increasing the resistance of the line, which acts as a cause to drastically reduce the movement speed of free electrons flowing in the wire, and therefore, more power is used for the same work. In particular, harmonics generated in the load device cause a voltage drop due to impedance from the power supply side (e.g., distribution board or distribution panel, etc.) to the end of the load device. This voltage drop causes voltage distortion in which the voltage waveform is distorted. The voltage distortion is amplified and acts as a cause of ‘various relay malfunctions, malfunctions in precision electronic devices, reduction in power factor, noise and vibration generation, damage to devices, and overheating’, resulting in enormous energy loss. Meanwhile, in the case of AC power, the harmonics that cause the above causes are mainly the 3rd harmonic, the 5th harmonic, and the 7th harmonic, etc., and the oxide mixture (140) of the present invention has the characteristic of efficiently absorbing the 3rd harmonic, the 5th harmonic, and the 7th harmonic, etc. in particular. Most home appliances installed indoors (e.g., refrigerators, fans, air conditioners, washing machines, etc.), various commercial electrical products installed in commercial facilities, and various industrial facilities installed in industrial facilities are equipped with load devices such as motors that generate harmonics. In addition, due to the development of electronic communication technology, numerous electronic products that generate electrical signals with frequencies are installed. Therefore, harmonics are inevitably generated in most places where electricity is used, including indoors, commercial facilities, or industrial facilities where AC power is supplied, and although there are differences depending on the cause and amount of harmonic generation, in most places where electricity is used, power is wasted due to harmonics.

The above thermal noise is a general term for noise generated by thermal disturbance. In the case of a load device, heat is inevitably generated due to the phase difference between the current waveform and the voltage waveform that is 90 degrees behind the starting current, and this heat generation causes thermal noise. As the temperature of thermal noise increases, the noise voltage increases and the frequency distribution becomes wider. The oxide mixture (140) of the present invention absorbs the thermal noise transmitted to the electrode portion (145) and then converts it into thermal energy and emits it. At this time, the oxide mixture (140) does not absorb the heat itself, but absorbs the frequency waveform of the thermal noise generated by the heat, and converts the absorbed thermal noise into thermal energy and emits it. Preferably, the oxide mixture (140) can maintain a surface temperature of within 18(+2)℃ (within 18℃, within a margin of error, within 20℃) while absorbing the harmonics and thermal noise and converting and emitting them into thermal energy.

According to the method of implementing the present invention, the oxide mixture (140) is characterized in that it absorbs harmonics and thermal noise applied to each electrode portion (145) at a specified ratio or more by using only N designated materials mixed in a specified weight percentage (wt(%)) range without a separate circuit (e.g., a circuit that generates inverse harmonics of harmonics generated in a power system during application or use of AC power to cancel out the harmonics), and/or without a separate coil, and/or without a separate magnetic material, and/or without a separate magnetic power supply, and/or without a separate energy supply (e.g., far infrared rays, etc.).

The above oxide mixture (140) is manufactured by mixing N designated materials including silicon (Si) and aluminum (Al) in a designated weight percentage (wt(%)) range at a predetermined mixing ratio, stirring while grinding to produce a mixed powder, oxidizing the mixed powder in a low-temperature drying furnace to produce an oxide mixture, firing the oxide mixture at a predetermined temperature in an electric furnace and then cooling to produce a sintered mixture, mixing the sintered mixture and a designated binder at a predetermined mixing ratio to liquefy, and then solidifying the liquefied mixture into a designated geometric structure while drying it after liquid contact with a first electrode portion (145) and a second electrode portion (145) that are mutually insulated from each other in a designated geometric relationship.

According to the method of implementing the present invention, in order to achieve a preset power saving rate (e.g., a power saving rate of 10% or more in an indoor environment using a refrigerator, an electric fan, an air conditioner, and a washing machine) by absorbing a specified rate or more of harmonic waves and thermal noise applied to each electrode portion (145) using only the oxide mixture (140), it is preferable that the mixed powder includes a specified weight percentage (wt(%)) of silicon (Si) among the N materials in a range of 10 to 40 wt(%), and a specified weight percentage (wt(%)) of aluminum (Al) in a range of 10 to 40 wt(%). In particular, in order to absorb harmonic waves and thermal noise applied to the electrode portion (145) by the oxide mixture (140) alone at a specified rate or higher, it is preferable that the sum of the weight percentages of silicon (Si) and aluminum (Al) included in the mixed powder be maintained within 60 (+5) wt (%) (within 60 wt (%), within 65 wt (%) within the margin of error).

According to the first mixture manufacturing embodiment of the present invention, the mixed powder can be produced by preparing raw materials manufactured for each of N designated substances, mixing the prepared raw materials for each substance at a mixing ratio corresponding to a designated weight percentage range of the mixed powder, and stirring while grinding them into a size of 100 mesh to 200 mesh using a grinder.

According to the second mixture manufacturing embodiment of the present invention, the mixed powder can be produced by preparing n (1 ≤ n ≤ N) ore raw materials containing N designated substances, mixing the prepared n ore raw materials at a mixing ratio corresponding to the designated weight percentage range of the mixed powder based on the weight percentage of each substance contained in each of the n ore raw materials, and stirring while crushing into a size of 100 mesh to 200 mesh using a crusher. In this case, the manufacturing cost of the oxide mixture (140) can be significantly lowered compared to the case where raw materials manufactured for each substance are used. However, even if ores have the same name, the content of minerals varies depending on the mine or producing area, and the end and content of additional substances contained in the ore also vary. Therefore, if the mixed powder is manufactured using only ores, the manufacturing cost can be lowered, but it may be difficult to control the designated 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 above raw materials and the type and content of the additives match the specified weight percentage range of the above mixed powder, an oxide mixture (140) that provides the specified power-saving performance within the error range can be manufactured at the lowest manufacturing cost. However, if not, the manufacturing cost may be low, but the power-saving performance may be lowered beyond the error range.

According to a third mixture manufacturing embodiment of the present invention, the mixed powder may be produced by preparing i (1 ≤ i ≤ N) ore raw materials including at least some of N designated substances, preparing j (1 ≤ j ≤ N, N = i ∪ j) material-specific raw materials that are not included in the i ore raw materials among the N designated substances or are included in the i ore raw materials but are insufficient to match the designated weight percentage range of the mixed powder, and then mixing the prepared i ore raw materials and j material-specific raw materials at a mixing ratio corresponding to the designated weight percentage range of the mixed powder based on the weight percentage of each substance included in the i ore raw materials, and stirring while pulverizing to a size of 100 mesh to 200 mesh using a pulverizer. In this case, the manufacturing cost of the oxide mixture (140) is lower than that of using raw materials manufactured for each substance, and the designated weight percentage range of the mixed powder can be easily controlled.

According to the fourth mixture manufacturing embodiment of the present invention, the mixed powder may be manufactured by preparing k (1 ≤ k ≤ N) waste raw materials (e.g., waste sludge from solar panels generated in the manufacturing process of solar panels used for solar power generation, waste sludge from solar panels used for solar power generation and discarded, or oxide mixtures (140) that have failed quality inspection, etc.) containing at least some of N designated substances, and then mixing the prepared k waste raw materials at a mixing ratio corresponding to a designated weight percentage range of the mixed powder based on the weight percentage of each substance included in the k waste raw materials, and stirring the mixture while grinding it to a size of 100 mesh to 200 mesh using a grinder. In this case, the manufacturing cost of the oxide mixture (140) can be significantly lowered than when using raw materials manufactured for each substance.

According to the fifth mixture manufacturing embodiment of the present invention, the mixed powder may be produced by preparing p (1 ≤ p ≤ N) waste raw materials (e.g., waste sludge from solar panels generated in the process of manufacturing solar panels used for solar power generation, or waste sludge from solar panels used for solar power generation and discarded, or oxide mixtures (140) that have failed quality inspection, etc.) containing at least some of N designated substances, preparing q (1 ≤ q ≤ N, N = p∪q) material-specific raw materials that are not included in the p waste raw materials among the N designated substances, or are included in the p waste raw materials but are insufficient to match the designated weight percentage range of the mixed powder, and then mixing the prepared p waste raw materials and q material-specific raw materials at a mixing ratio corresponding to the designated weight percentage range of the mixed powder based on the weight percentages of the substances included in the p waste raw materials, and stirring the mixture while grinding to a size of 100 mesh to 200 mesh using a grinder. In this case, the manufacturing cost of the oxide mixture (140) is significantly lower than when raw materials manufactured for each material are used, and the specified weight percentage range of the mixed powder can be easily controlled.

According to the sixth mixture manufacturing embodiment of the present invention, the mixed powder may be produced by preparing s (1 ≤ s ≤ N) ore raw materials and t (1 ≤ t ≤ N) waste raw materials, which contain at least some of N designated materials, as raw materials, and preparing u (1 ≤ u ≤ N, N = s∪ t ∪ u) material-specific raw materials that are not included in the s ore materials and t waste raw materials among the N designated materials or are included in the s ore materials and t waste raw materials but are insufficient to match the designated weight percentage range of the mixed powder, and then mixing the prepared s ore materials, t waste raw materials, and u material-specific raw materials at a mixing ratio corresponding to the designated weight percentage range of the mixed powder based on the weight percentages of the materials included in the s ore materials and the t waste raw materials, and stirring while pulverizing to a size of 100 mesh to 200 mesh through a pulverizer. In this case, the manufacturing cost of the oxide mixture (140) is lower than when raw materials manufactured for each material are used, and the specified weight percentage range of the mixed powder can be easily controlled.

Meanwhile, when manufacturing a mixed powder through at least one of the second to sixth mixed powder manufacturing examples, considering the types or contents of materials contained in representative ore raw materials or waste raw materials available domestically or additives contained in the raw materials, the mixed powder may contain various additives contained in the ore raw materials or waste raw materials. In this case, in order to absorb harmonic waves and thermal noise applied to the electrode unit (145) at a specified constant rate or more using only the oxide mixture (140), the sum of the weight percentages of silicon (Si) and aluminum (Al) contained in the mixed powder may be maintained at a weight percentage of 55 wt(%) or less.

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

Meanwhile, according to the method of implementing the present invention, the N designated substances included in the mixed powder may further include, in addition to the above substances, one or more substances among zirconium (Zr) within 5 wt (%), sodium (Na) within 5 wt (%), potassium (K) within 5 wt (%), calcium (Ca) within 5 wt (%), titanium (Ti) within 5 wt (%), zirconium boride (ZrB2) within 5 wt (%), titanium compound (TiB2) within 5 wt (%), and barium titanium (BaTi) within 5 wt (%). Meanwhile, some of the substances within 5 wt (%) may be omitted, and the present invention is not limited thereby.

Meanwhile, when manufacturing a mixed powder through at least one of the second to sixth mixed powder manufacturing examples, considering the types or contents of materials contained in representative ore raw materials or waste raw materials available domestically or additives contained in the raw materials, the N designated materials contained in the mixed powder are 26.8 (wt(%)) silicon (Si), 26.0 (wt(%)) aluminum (Al), 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), It can be made by including 2.00 (wt(%)) of zirconium boride (ZrB2), 1.20 (wt(%)) of titanium compound (TiB2), and 3.10 (wt(%)) of barium titanium (BaTi).

Meanwhile, when a mixed powder is generated by mixing and stirring N designated substances at a preset mixing ratio matching a designated weight percentage range through at least one of the first to sixth mixture production examples, the mixed powder is then put into a low-temperature drying furnace, oxidized while supplying oxygen through dried air, and then cooled through nitrogen (N2) to generate an oxidized mixture stabilized in the air. Preferably, the mixed powder is oxidized for 45 hours or more through dried air at 80°C (10°C) in a low-temperature drying furnace to generate an oxidized mixture. That is, since some of the N designated substances included in the mixed powder (e.g., silicon (Si), sodium (Na), aluminum (Al), etc.) may spontaneously ignite or explode if moisture (e.g., oxygen (O2) and hydrogen (H), etc.) is present in the process of combining with oxygen (O2), it is preferable that the oxidized mixture be manufactured by sufficiently and slowly oxidizing using dried air.

According to the method of the present invention, among the N designated substances included in the mixed powder, silicon (Si) may be oxidized to silicon dioxide (SiO2), and the aluminum may be oxidized to aluminum oxide (AlO2). Meanwhile, among the N designated substances included in the mixed powder, magnesium (Mg) may be oxidized to magnesium oxide (MgO), and iron (Fe) may be oxidized to iron oxide (Fe2O3). Other substances may also be oxidized to zirconium oxide (ZrO2), sodium superoxide (NaO2), potassium superoxide (K2O), calcium oxide (CaO), titanium oxide (TiO2), zirconium boride (ZrB2), a titanium compound (TiB2), barium titanate (BaTiO3), etc. The oxidized mixture including the oxidized substances remains stable even in a high humidity state in the air. Meanwhile, if the substance included in the above mixed powder is in an oxidized state, the oxidation process can be omitted, and the present invention is not limited thereby.

When the above-mentioned oxide mixture is generated, the oxide mixture is fired in an electric furnace at a temperature of 890°C to 970°C for 10 hours or more and cooled with nitrogen (N2) to generate a fired mixture. Through the fired process, the fired mixture can maintain a stable state in any air environment, and in particular, the dielectric properties are stably activated. Meanwhile, when the material included in the mixed powder is already oxidized and stabilized or when the oxide mixture is oxidized and then stabilized, the fired process may be omitted, and the present invention is not limited thereto.

Once the above-mentioned sintered mixture is created, a designated binder (e.g., an inorganic compound that binds mineral powder to liquefy it) is mixed with the sintered mixture at a preset mixing ratio to liquefy it, thereby creating a liquid mixture. Here, the mixing ratio of the sintered mixture and the binder is preferably such that the ratio of the binder to the sintered mixture is within 10%.

In order to manufacture an oxide mixture (140) of a designated geometric structure, a first electrode part (145) and a second electrode part (145) made of a highly conductive metal material (e.g., copper (Cu), etc.) are arranged and fixed in a designated geometric relationship so as to be mutually insulated from each other on a frame manufactured with a designated geometric structure, and a manufacturing frame is prepared that is provided with a power contact for electrically connecting to a designated terminal for power supply of the power plug part (105) on one side of each electrode part (145) and a wiring contact for electrically connecting to a designated wiring part (130) on the other side of each electrode part (145). It is preferable that the manufacturing frame be provided with each contact so that the power contact and the wiring contact are exposed to the outside of the oxide mixture (140) when the liquid mixture is poured into the manufacturing frame and dried to manufacture the oxide mixture (140).

According to the method of implementing the present invention, the geometric relationship for arranging the electrode portions (145) in the oxide mixture (140) preferably includes a relationship in which each electrode portion (145) is arranged at a distance of 1 cm to 1.5 cm to maximize the occurrence of electric polarization (or dielectric polarization) between the electrode portions (145). For example, when an AC power of 250 V/16 A is applied to two designated electrode portions (145) provided in the oxide mixture (140), the interval at which the electric polarization (or dielectric polarization) phenomenon is activated between each electrode portion (145) is 0.9 cm to 2.2 cm. According to the applicant's experiment, when the interval between the two electrode portions (145) provided in the oxide mixture (140) is 1 cm to 1.5 cm, the electric polarization (or dielectric polarization) phenomenon can be maximized. Meanwhile, it is clearly stated that even if the spacing between each electrode part (145) is 0.9 cm to 2.2 cm, it can be attributed to the scope of the present invention.

Meanwhile, according to the implementation method of the present invention, the electric polarization (or dielectric polarization) phenomenon is not maximized immediately when AC power is applied to the two electrode portions (145) provided in the oxide mixture (140), and according to the applicant's experiment, the electric polarization (or dielectric polarization) phenomenon is maximized or can be stably maintained in a maximized state after at least 7 minutes (preferably, 10 minutes or more) have passed since AC power was applied to each electrode portion (145) of the oxide mixture (140).

According to the method of implementing the present invention, it is preferable that the geometric relationship for arranging the electrode portions (145) in the oxide mixture (140) includes a relationship for arranging two designated electrode portions (145) in parallel. For example, when the cross-section of the electrode portions (145) provided in the oxide mixture (140) is '-', it is preferable that the two electrode portions (145) provided in the oxide mixture (140) are provided in a parallel relationship like '- -'. Alternatively, when the cross-section of the electrode portions (145) provided in the oxide mixture (140) is '|', it is preferable that the two electrode portions (145) provided in the oxide mixture (140) are provided in a parallel relationship like '| |'.

According to the method of implementing the present invention, it is preferable that the geometric relationship for arranging the electrode portions (145) in the oxide mixture (140) includes a relationship in which two designated electrode portions (145) that are mutually insulated are arranged in an opposing manner. For example, when the cross-section of the electrode portions (145) provided in the oxide mixture (140) is '-', it is preferable that the two electrode portions (145) provided in the oxide mixture (140) are arranged in an opposing manner like '- -'. Alternatively, when the cross-section of the electrode portions (145) provided in the oxide mixture (140) is '|', it is preferable that the two electrode portions (145) provided in the oxide mixture (140) are arranged in an opposing manner like '| |'.

According to the method of implementing the present invention, the geometric relationship for arranging the electrode portions (145) in the oxide mixture (140) may include a relationship for arranging two designated electrode portions (145) in a hierarchical structure. For example, when the cross-section of the electrode portions (145) provided in the oxide mixture (140) is '-', the two electrode portions (145) provided in the oxide mixture (140) may be arranged in a hierarchical structure such as a '-_' relationship or a '_ -' relationship.

According to the method of implementing the present invention, it is preferable that the geometric relationship for arranging the electrode portions (145) in the oxide mixture (140) includes a relationship in which the vertical shortest distance between the surface of each electrode portion (145) provided inside the oxide mixture (140) and the outer surface of the oxide mixture (140) is spaced apart by at least 0.5 cm.

According to an extended implementation method of the present invention, the oxide mixture (140) may further include a conductive electrode that is electrically connected to a ground line portion (135) connected to the ground portion (120) and electrically connected to a ground contact of the power plug portion (105), in addition to the electrode portion (145) electrically connected to the wiring portion (130) and the conductor portion (155), and the present invention is not limited thereto.

According to the method of implementing the present invention, since the harmonic waves and thermal noise are transmitted along the surface of the conductive metal material and the oxide mixture (140) is manufactured in a rectangular parallelepiped structure, it is preferable that each electrode part (145) include an electrode plate shape of a designated geometric structure. Preferably, when supplying AC power of 250 V/16 A through the outlet device (100), in order to absorb a designated constant ratio or more of the harmonic waves and thermal noise with only the oxide mixture (140), it is preferable that each electrode part (145) 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 (145). However, the numerical value of the geometric structure of the electrode plate is the minimum numerical value for absorbing harmonics and thermal noise by a specified percentage or more with only the oxide mixture (140) under the AC power condition of 250 V/16 A, and the numerical value of the geometric structure of each electrode part (145) can be adjusted in the direction of increasing the contact area where each electrode part (145) and the oxide mixture (140) come into contact. Meanwhile, when the voltage amount supplied through the outlet device (100) is set to be a certain percentage larger than 250 V or the current amount to be supplied through the outlet device (100) is set to be a certain percentage larger than 16 A, the minimum numerical value for the geometric structure of each electrode part (145) can be adjusted in a form capable of producing an external area that is wider by a certain percentage or more than the calculated numerical value.

According to the method of implementing the present invention, in order to absorb a specified percentage or more of harmonic waves and thermal noise applied to the electrode portion (145) only with the oxide mixture (140), it is preferable that each electrode portion (145) and the oxide mixture (140) be maintained in contact with a specified contact area or more. Preferably, when supplying AC power of 250 V/16 A through the outlet device (100), each electrode portion (145) preferably includes a contact area of at least 3.6 cm2 or more in contact with the oxide mixture (140) for each electrode portion (145). For example, if the geometric structure of each electrode part (145) is 3 cm in length, 0.5 cm in width, and 0.1 cm in thickness, both ends of each electrode part (145) may not come into contact with the oxide mixture (140) to form a designated contact point, so it is preferable that the contact area where the electrode part (145) of the geometric structure comes into contact with the oxide mixture (140) is 3.6 cm2 or more. However, the numerical value of the contact area of the electrode plate is the minimum numerical value for absorbing harmonics and thermal noise by a specified percentage or more with only the oxide mixture (140) under the AC power condition of 250V/16A, and the numerical value of the contact area of each electrode part (145) can be adjusted in the direction of increasing the contact area where each electrode part (145) comes into contact with the oxide mixture (140), and the wider the contact area where each electrode part (145) comes into contact with the oxide mixture (140) within the oxide mixture (140), the more stably the harmonics and thermal noise can be absorbed by a specified percentage or more. Meanwhile, when the voltage supplied through the outlet device (100) is set to be a certain percentage larger than 250V or the current supplied through the outlet device (100) is set to be a certain percentage larger than 16A, the minimum numerical value for the contact area of each electrode part (145) can be adjusted in a form capable of producing a contact area that is wider by a specified percentage or more than the calculated numerical value.

According to the method of implementing the present invention, in order to absorb harmonic waves and thermal noise applied to the electrode portion (145) by a specified ratio or more using only the oxide mixture (140), it is preferable that the oxide mixture (140) maintain a volume greater than a specified volume. Preferably, when power of 250V/16A is supplied through the above-mentioned outlet device (100), the geometric structure of the electrode portion (145) is 3cm or more, width 0.5cm or more, thickness 0.1cm or more, and the first electrode portion (145) and the second electrode portion (145) are arranged in an insulated manner with a distance of at least 1cm between them in the oxide mixture (140), and the distance between the surface of each electrode portion (145) and the surface of the oxide mixture (140) is at least 0.5cm or more, so in this case, the volume of the oxide mixture (140) is numerically 9.9㎤ or more, and in consideration of the error value, in order to absorb a specified constant ratio or more of harmonic waves and thermal noise applied to the electrode portion (145) with only the oxide mixture (140), it is preferable that the volume of the oxide mixture (140) including two electrode portions (145) including the above-mentioned geometric structure includes a volume of at least 10㎤ or more. However, the numerical value of the volume of the oxide mixture (140) is the minimum numerical value for absorbing harmonics and thermal noise at a specified rate or more with only the oxide mixture (140) under AC power conditions of 250 V/16 A, and the numerical value of the volume of the oxide mixture (140) can be adjusted in the direction in which the volume of the oxide mixture (140) increases, and the larger the volume of the oxide mixture (140), the more stably the harmonics and thermal noise can be absorbed at a specified rate or more.

Meanwhile, the amount and size of harmonic waves and thermal noise to be absorbed through the electrode portion (145) provided in the oxide mixture (140) are proportional to the number and load amount of load devices that receive power through the plug insertion portion (110) of the outlet device (100). According to the applicant's experiment, it has been confirmed that when the volume of the oxide mixture (140) is about 10㎤, it is possible to absorb harmonic waves and thermal noise generated from load devices of up to two motors that rotate fan blades (e.g., up to one per 5㎤) at a specified constant rate or more. Accordingly, if the number of load devices per plug insertion part (110) of the outlet device (100) is calculated to be 1.5 on average, and the number of plug insertion parts (110) provided in the outlet device (100) is calculated to be 6 at most, the volume of the oxide mixture (140) for absorbing harmonic waves and thermal noise applied to the electrode part (145) by a specified constant ratio or more with only the oxide mixture (140) is preferably 45㎤ or more.

Meanwhile, in the present invention, the oxide mixture (140) provided in the outlet device (100) is characterized in that it not only directly absorbs harmonics and thermal noise generated by a load device that receives power through the plug insertion portion (110) of the outlet device (100), but also indirectly absorbs harmonics and thermal noise generated by other load devices that do not receive power through the plug insertion portion (110) but share AC power supplied from the distribution board or branch board. As a result, the oxide mixture (140) provided in the outlet device (100) basically absorbs harmonics and thermal noise generated from a plurality of load devices. Meanwhile, in a typical electricity usage environment, excluding some commercial or industrial facilities where load devices are concentrated, the number of load devices operating simultaneously is 9 or less, and the volume of the oxide mixture (140) for absorbing harmonics and thermal noise generated thereby at a specified constant rate or more is preferably 45㎤ or more. However, the numerical value of the volume of the oxide mixture (140) is the minimum numerical value for absorbing harmonics and thermal noise by a specified percentage or more with only the oxide mixture (140) in a normal electrical use environment, and the numerical value of the volume of the oxide mixture (140) can be adjusted in the direction in which the volume of the oxide mixture (140) increases, and the larger the volume of the oxide mixture (140), the more stably the harmonics and thermal noise can be absorbed by a specified percentage or more.

Meanwhile, according to the method of implementing the present invention, the geometric structure of the outer shape of the oxide mixture (140) can be variously adapted according to the space inside the outlet device (100) in which the oxide mixture (140) is mounted.

According to the first oxide mixture mounting method of the present invention, the oxide mixture (140) can be provided in the front part of the body part (160) that receives AC power through the power plug part (105) as in the embodiment of Drawing 1.

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

According to the third oxide mixture mounting method of the present invention, the oxide mixture (140) can be provided in the lower part of the body part (160) corresponding to the lower part of the plug insertion part (110).

According to the fourth oxide mixture mounting method of the present invention, the oxide mixture (140) can be provided on the rear part of the body part (160) corresponding to the opposite side of the part that receives AC power through the power plug part (105).

According to the method of implementing the present invention, it is preferable that the manufacturing mold includes an internal space for forming a geometric structure capable of mounting or fixing the oxide mixture (140) in a designated mounting space formed in the body portion (160) of the outlet device (100).

When the above-mentioned production mold is prepared, the liquefied liquid mixture is poured into the production mold, and the liquid mixture is allowed to adhere to each electrode portion (145) arranged in a designated geometric relationship while drying at room temperature to produce an oxide mixture (140) solidified in a designated geometrical structure corresponding to the mold.

According to the method of implementing the present invention, before the liquid mixture is poured into the production mold and the solidification of the liquid state proceeds, vibration of a specified frequency is applied to the production mold so that the liquid mixture adheres to each electrode part (145) without any gaps or voids.

When the liquid mixture poured into the above-mentioned production mold is dried at room temperature and solidified, the above-mentioned production mold is removed to separate the solidified oxide mixture (140), and then a designated quality inspection is performed.

According to the method of implementing the present invention, it is preferable that the insulation resistance between the two electrode portions (145) of the oxide mixture (140) is measured to be 100 MΩ or more or infinite when a voltage of 1000 V (100 V) is applied to the two electrode portions (145) that are mutually insulated from each other in a specified geometric relationship.

According to the method of implementing the present invention, the oxide mixture (140) preferably has a compressive strength of 350 to 460 kgf/cm2 and a tensile strength of 27 to 35 kgf/cm2 in a solidified state. Therefore, the solidified oxide mixture (140) should not have any externally cracked or broken portions. To confirm this, a visual inspection or a designated non-destructive inspection can be performed.

When the oxide mixture (140) is manufactured through the above process, the oxide mixture (140) is mounted or fixed in the mounting space formed inside the body (160) of the outlet device (100), and the first conductor (155) electrically connected to one terminal of the power plug (105) and the power contact provided in the first electrode portion (145) of the oxide mixture (140) are electrically connected, and at the same time, the other terminal of the power plug (105) and the first electrode portion (145) of the oxide mixture (140) are electrically connected to the power contact provided in the second electrode portion (145) that is arranged to be insulated by forming a designated geometric relationship with the first electrode portion (145) of the oxide mixture (140), and the first wiring portion (130) that electrically connects the M first contact portions (125) provided in the first terminal insertion hole (115) of one side of each of the M plug insertion portions (110) and the M first contact portions (125) provided in the first terminal insertion hole (115) of the M plug insertion portions (110) are electrically connected to the M first contact portions (125) provided in the first terminal insertion hole (115) of the M plug insertion portions (110) and the M first contact portions (125) provided in the oxide mixture (140) are electrically connected. The designated wiring contacts of the first electrode portion (145) are electrically connected, and at the same time, the second wiring portion (130) that electrically connects the M second contact portions (125) provided in the second terminal insertion holes (115) on the other side of the M plug insertion portions (110) is electrically connected to the designated wiring contacts of the second electrode portion (145) provided in the oxide mixture (140), and an operating module is mounted to manufacture the outlet device (100).

According to the method of implementing the present invention, by electrically connecting the power contact of the electrode part (145) provided in the oxide mixture (140) to the terminal of the power plug part (105) and simultaneously electrically connecting the wiring contact of the electrode part (145) provided in the oxide mixture (140) to the wiring part (130) which is electrically connected to the M contact parts (125) provided in the terminal insertion holes (115) of each of the M plug insertion parts (110), the outlet device (100) can perform the function of directly saving power by serially absorbing the harmonics and thermal noise of the AC power applied to an electrical product or another standing outlet through the contact part (125) of the plug insertion part (110).

Meanwhile, according to the implementation method of the present invention, by electrically connecting the power contact of the electrode part (145) provided in the oxide mixture (140) to the terminal of the power plug part (105), the outlet device (100) can indirectly save power by absorbing in parallel the harmonics and thermal noise of the AC power supplied to other electrical appliances through the contact part of the plug insertion part of the wall-type outlet or other standing outlet that shares the AC power supplied from the distribution board or distribution board in a situation where the power plug part (105) is inserted into the plug insertion part of the wall-type outlet or other standing outlet and AC power is supplied from the distribution board or distribution board, and also indirectly save power by absorbing in parallel the harmonics and thermal noise of the AC power supplied to other electrical appliances through the contact part of the plug insertion part of the other wall-type outlet that shares the AC power supplied from the distribution board or distribution board.

According to the method of implementing the present invention, the above-described stand-alone outlet device (100) may be provided with a switch unit (150) including a switch that supplies or cuts off power applied to the wiring unit (130) to M plug insertion units (110). It is preferable that the switch unit (150) be provided between the wiring unit (130) and the oxide mixture (140). In this case, the switch unit (150) may supply or cut off power applied to the wiring unit (130) in an electrical connection state in which each conductor unit (155) and the wiring unit (130) are electrically connected to each electrode unit (145) of the oxide mixture (140), or power applied to the wiring unit (130) in a state in which the electrical connection state is cut off, to the M plug insertion units (110).

According to the method of implementing the present invention, by providing the switch unit (150) between the wiring unit (130) and the oxide mixture (140), the outlet device (100) can indirectly save power by absorbing in parallel the harmonics and thermal noise of the AC power supplied to other electrical appliances through the contact portion of the plug insertion portion of the wall-type outlet or other standing outlet that shares the AC power supplied from the distribution panel or distribution board in a situation where the power plug unit (105) is inserted into the plug insertion portion of a wall-type outlet or other standing outlet and AC power is supplied from a distribution panel or distribution board, and also indirectly save power by absorbing in parallel the harmonics and thermal noise of the AC power supplied to other electrical appliances through the contact portion of the plug insertion portion of another wall-type outlet that shares the AC power supplied from the distribution panel or distribution board.

Meanwhile, according to the implementation method of the present invention, the oxide mixture (140) can reach a maximum value in the rate of absorption of harmonics and thermal noise and maintain that state after at least 7 minutes (preferably, 10 minutes) have passed since AC power is applied to each electrode portion (145). In this state, when the AC power applied to the electrode portion (145) of the oxide mixture (140) is cut off, the rate of absorption of harmonics and thermal noise by the oxide mixture (140) gradually decreases. Therefore, unlike a conventional power-saving method of cutting off standby power, the outlet device (100) has the characteristic that the power-saving function is maximized or maintained only when AC power is continuously applied to the oxide mixture (140) through the power plug portion (105).

Drawing 2 is a block diagram showing the functional configuration of an operating module (200) according to an implementation method of the present invention.

More specifically, the drawing 2 is a block diagram showing the functional configuration of the operating module (200) mounted on the stand-alone outlet device (100) of the drawing 1, and a person having ordinary knowledge in the technical field to which the present invention pertains may infer various implementation methods (e.g., implementation methods in which some components are omitted, subdivided, or combined) for the functional configuration of the operating module (200) by referring to and/or modifying the drawing 2, but the present invention includes all of the inferred implementation methods, and its technical features are not limited to only the implementation methods illustrated in the drawing 2.

Referring to Drawing 2, the operating module (200) electrically connects the first conductor part (155) and the first wiring part (130) to the first electrode part (145) of the oxide mixture (140) and electrically connects the second conductor part (155) and the second wiring part (130) to the second electrode part (145) of the oxide mixture (140) and maintains an electrical connection state in which the second conductor part (155) and the second wiring part (130) are electrically connected to the second electrode part (145) of the oxide mixture (140), or temporarily releases the electrical connection state so that the first electrode part (145) and the second electrode part (145) of the oxide mixture (140) are electrically insulated from the first conductor part (155) and the second conductor part (155) and the first wiring part (130) and the second wiring part (130) in the first conductor part (155) and the second conductor part (155). A processing unit (210) that switches to a direct power supply state in which power can be directly supplied to the wiring unit (130) and then processes the electrical connection state to be restored, and a sensor unit (205) that is electrically connected to the first wiring unit (130) and the second wiring unit (130) and senses a power-saving sensing value corresponding to the amount of power used by being supplied to the first wiring unit (130) and the second wiring unit (130) through the first electrode unit (145) and the second electrode unit (145) of the oxide mixture (140) when the electrical connection state is maintained through the processing unit (210), and senses a non-power-saving sensing value corresponding to the amount of power used by being directly supplied to the first wiring unit (130) and the second wiring unit (130) from the first conductor unit (155) and the second conductor unit (155) when the electrical connection state is temporarily released, and the sensed power-saving sensing value and the non-power-saving sensing value are combined into one. It includes a generation unit (215) that generates designated processing information using the above, a communication unit (220) that transmits a short-range wireless signal including the processing information or transmits the processing information to an app of a designated wireless terminal through a designated short-range wireless communication, and further includes an output unit (240) that outputs the processing information, and further includes a storage unit (230) that stores setting information for generating designated processing information using at least one of a power-saving sensing value and a non-power-saving sensing value sensed through the sensor unit (205). Meanwhile, the operation module (200) further includes a power unit (225) that is electrically connected to the first wiring unit (130) and the second wiring unit (130) to generate designated operating power and apply it to each component of the operation module (200), and may further include an operation unit (235) that receives a user operation.

The power supply unit (225) is electrically connected to the first wiring unit (130) and the second wiring unit (130) provided in the stand-alone outlet device (100) to receive AC power, generate a designated operating power, and supply it to each component of the operating module (200). Preferably, each component of the operating module (200) can use DC power as the operating power, and in this case, the power supply unit (225) is electrically connected to the first wiring unit (130) and the second wiring unit (130) to rectify the applied AC power into DC power of one or more designated voltage values and current values and supply it to each component of the operating module (200).

According to the method of implementing the present invention, the power supply unit (225) may have a built-in battery that charges and stores the applied operating power, and in this case, the operating module (200) may operate for a certain period of time even under conditions where the AC power is not applied.

The above processing unit (210) maintains an electrical connection state in which the first conductor part (155) and the first wiring part (130) are electrically connected to the first electrode part (145) of the oxide mixture (140) and the second conductor part (155) and the second wiring part (130) are electrically connected to the second electrode part (145) of the oxide mixture (140), thereby enabling the oxide mixture (140) to absorb harmonics and thermal noise transmitted to the electrode part (145) through the conductor part (155) and/or the wiring part (130).

Meanwhile, the processing unit (210) can temporarily release the electrical connection state according to a specified rule and switch to a direct power supply state. In this case, the processing unit (210) can process the AC power supplied through the power plug unit to be directly applied to the contact portion within the terminal insertion hole on one side of each of the M plug insertion portions via the conductor portion (155) and the wiring portion (130). That is, it is preferable that the processing unit (210) process the AC power supply state to be maintained even when the electrical connection state is temporarily released.

According to the method of implementing the present invention, the oxide mixture (140) can reach a maximum value in the rate of absorption of harmonics and thermal noise after at least 7 minutes (preferably, 10 minutes) have passed since AC power is applied to each electrode unit (145) and maintain that state. In this state, when the AC power applied to the electrode unit (145) of the oxide mixture (140) is cut off, the rate of absorption of harmonics and thermal noise by the oxide mixture (140) gradually decreases. Accordingly, it is preferable that the processing unit (210) limit the time for temporarily releasing the electrical connection state to a specified reference time (e.g., within 1 minute, preferably within several seconds) so that the rate of absorption of harmonics and thermal noise by the oxide mixture (140) does not decrease.

According to the method of implementing the present invention, the processing unit (210) can process to temporarily release the electrical connection state periodically while maintaining the electrical connection state, switch to a direct power supply state, and then return to the state.

According to the method of implementing the present invention, the processing unit (210) checks whether the amount of power used while maintaining the electrical connection state changes by more than a preset reference value, and if the amount of power used changes by more than the reference value, the electrical connection state can be temporarily released, and then the state can be converted to a direct power supply state and then returned.

The sensor unit (205) senses a designated sensing value in conjunction with at least one of the conductor unit (155) and the wiring unit (130). If the processing unit (210) maintains the electrical connection state, the sensor unit (205) can sense a designated power-saving sensing value corresponding to a state in which harmonics and thermal noise are absorbed through the oxide mixture (140). If the processing unit (210) temporarily releases the electrical connection state, the sensor unit (205) can sense a designated non-power-saving sensing value corresponding to a state in which AC power applied through the power plug unit is directly applied to a contact portion within a terminal insertion hole on one side of each of the M plug insertion portions through the conductor unit (155) and the wiring unit (130) (e.g., a state in which harmonics and thermal noise are not absorbed through the oxide mixture (140).

According to the method of implementing the present invention, the sensor unit (205) includes a power amount sensor unit (205) having a power amount measurement sensor that senses power amount and a converter that converts an analog value sensed through the power amount measurement sensor into a digitalized sensing value. Preferably, the sensor unit (205) electrically connects the power amount measurement sensor to the first wiring unit (130) and the second wiring unit (130) provided in the stationary outlet device (100), and senses a designated power saving sensing value including the power amount used for power saving through the oxide mixture (140) when the electrical connection state is maintained through the processing unit (210). Meanwhile, when the electrical connection state is temporarily disconnected through the processing unit (210), the sensor unit (205) can sense a designated non-power-saving sensing value including the amount of non-power-saving power used for AC power directly applied to the contact unit through the conductor unit (155) and the wiring unit (130) without using the oxide mixture (140).

The storage unit (230) stores designated setting information set to generate designated processing information using at least one of the power-saving sensing value and the non-power-saving sensing value sensed through the sensor unit (205). Preferably, the setting information (or at least a portion of the setting information) may be stored in the storage unit (230) at the time of manufacturing the outlet device (100) (or the operating module (200)).

According to the method of implementing the present invention, the storage unit (230) can store designated setting information (or at least a portion of the setting information) set by the user. Preferably, the output unit (240) outputs an interface for receiving designated setting information, the operation unit (235) inputs and processes the setting information based on the interface, and the storage unit (230) can store the setting information input through the operation unit (235) in a designated storage area.

The above generation unit (215) generates designated processing information to be output through the output unit (240) using at least one of the power-saving sensing value and the non-power-saving sensing value sensed through the sensor unit (205).

According to the method of implementing the present invention, the generation unit (215) can generate processing information including at least one sensing value among the power-saving sensing value and the non-power-saving sensing value sensed through the sensor unit (205). Preferably, the generation unit (215) can generate processing information including power amount information corresponding to the power-saving sensing value (e.g., power amount information used for power-saving through the oxide mixture (140)), or can generate processing information including power amount information corresponding to the non-power-saving sensing value (e.g., power amount information directly applied and used from each conductor unit (155) to each wiring unit (130).

Meanwhile, when setting information for calculating electricity rates using power amount information (e.g., rate information per power amount, progressive rate information for applying a progressive rate system for each designated progressive rate section, etc.) is stored in the storage unit (230), the generation unit (215) can generate processing information including rate information corresponding to the power amount information used for energy conservation based on the setting information.

Meanwhile, the above-mentioned generation unit (215) can generate information on the amount of power saved by subtracting the amount of power corresponding to the power-saving sensing value sensed while the electrical connection state is maintained from the amount of power corresponding to the non-power-saving sensing value temporarily sensed while the electrical connection state is temporarily released.

If setting information for calculating electricity rates using power information is stored in the storage unit (230), the generation unit (215) can generate processing information including saved rate information corresponding to the saved power information based on the setting information.

According to the method of implementing the present invention, when setting information for generating processing information specified in the storage unit (230) is stored, the generation unit (215) can generate the specified processing information by using one or more of the sensed power-saving sensing values and non-power-saving sensing values sensed through the sensor unit (205) based on the stored setting information.

In the case where setting information for calculating accumulated power information (e.g., period information for calculating accumulated power used for power saving over a certain period of time through the oxide mixture (140) or time information for initializing accumulation of accumulated power, etc.) is stored in the storage unit (230) according to the implementation method of the present invention, the generation unit (215) can generate processing information including accumulated power information for power saving over a certain period of time through the oxide mixture (140) by using the power information included in the power saving sensing value based on the setting information.

Meanwhile, if setting information for calculating electricity rates using accumulated power information is stored in the storage unit (230), the generation unit (215) can generate processing information including rate information corresponding to accumulated power information used for energy saving over a certain period of time based on the setting information.

Meanwhile, according to the implementation method of the present invention, the storage unit (230) stores in a designated storage area, through the processing unit (210), a designated power-saving sensing value including an amount of power continuously sensed through the sensor unit (205) while the electrical connection state is maintained, and a designated non-power-saving sensing value including an amount of power temporarily sensed through the sensor unit (205) while the electrical connection state is temporarily released, in a time-series manner, and in this case, the generation unit (215) calculates cumulative power amount information used for power-saving for a designated period of time through the oxide mixture (140) based on the amount of power corresponding to the power-saving sensing value sensed while the electrical connection state is maintained, and generates information on the relationship between the stored power-saving sensing value and the non-power-saving sensing value (for example, a relationship for interpolating a section of some non-sensed non-power-saving sensing values using a change pattern of validly sensed power-saving sensing values, etc.) for a designated period of time. In the case where power is directly supplied from each conductor section (155) to each wiring section (130) while being electrically insulated from the electrode section (145), estimated non-power-saving cumulative power information can be calculated, and processing information including saved cumulative power information can be generated by subtracting the power-saving cumulative power information from the calculated non-power-saving cumulative power information.

If setting information for calculating electricity rates using accumulated power information is stored in the storage unit (230), the generation unit (215) may calculate power-saving usage rate information corresponding to the accumulated power information used for power saving over a certain period of time and non-power-saving rate information corresponding to the non-power-saving accumulated power information based on the setting information, and may generate processing information including the saved rate information by deducting the power-saving usage rate information from the calculated non-power-saving rate information.

Meanwhile, when at least one designated processing information is generated through the generation unit (215), the communication unit (220) transmits a short-range wireless signal including the processing information according to a designated wireless standard or transmits the processing information to an app of a designated wireless terminal through a designated short-range wireless communication. Meanwhile, the storage unit (230) can store and manage the generated processing information in a designated storage area for a certain period of time (e.g., until the generated processing information is transmitted or sent through the communication unit (220) or until the next processing information is generated).

According to the implementation method of the present invention, the communication unit (220) can encode the processing information into a short-range wireless signal broadcasted in a short-range without specifying a receiving end according to a designated short-range wireless standard and transmit the encoded processing information in a short-range wireless signal. For example, the communication unit (220) can encode the processing information into a BLE signal of Bluetooth standard 4.0 or later and transmit the encoded processing information in a short-range wireless signal.

According to the method of implementing the present invention, the communication unit (220) may perform a pairing procedure with a designated wireless terminal at least once according to a designated short-range wireless standard, and may perform a function of transmitting the processing information to an app of the paired wireless terminal through two-way short-range wireless communication according to the short-range wireless standard. For example, the communication unit (220) may perform a pairing procedure with a designated wireless terminal according to a Bluetooth standard, and may perform a function of transmitting the processing information to an app of the paired wireless terminal through two-way Bluetooth communication according to the Bluetooth standard.

Meanwhile, according to the method of implementing the present invention, the short-range wireless standard for transmitting a short-range wireless signal or for short-range wireless communication is not limited to the Bluetooth exemplified above, and it is clearly stated that it includes all short-range wireless standards that transmit a wireless signal or enable two-way wireless communication in a designated short-range (e.g., within 30 m, up to 100 m), such as WiFi or Zigbee.

Meanwhile, if the operation module (200) is equipped with the output unit (240), the output unit (240) can output the generated/stored processing information. Meanwhile, if processing information including multiple pieces of information is generated through the generation unit (215) and the multiple pieces of information generated cannot be integrated and output through the output unit (240), the output unit (240) can change and output the information to be output according to a preset rule and/or change and output the information to be output in response to a user operation through the operation unit (235).

Drawing 3 is a drawing showing the manufacturing process of a stand-alone outlet device (100) according to the method of implementing the present invention.

In more detail, the drawing 3 shows an oxide mixture (140) manufactured using N (N≥2) designated materials and first electrode parts (145) and second electrode parts (145) arranged in a mutually insulating manner in a designated geometric relationship inside a wall-mounted outlet device (100), and connecting in series the AC power supplied through the power plug part (105) and the electrode parts (145) in the oxide mixture (140) and the contact parts (125) provided on the side of the M plug insertion parts (110), thereby directly saving power by serially absorbing harmonics and thermal noise of the AC power supplied to an electrical appliance or another wall-mounted outlet through the contact parts (125) of the plug insertion part (110), and at the same time, sharing the AC power supplied from the distribution board or the distribution panel in a state where the power plug part (105) is inserted into the plug insertion part of the wall-mounted outlet or another wall-mounted outlet. The process of manufacturing a stationary outlet device (100) that indirectly saves power by absorbing in parallel harmonics and thermal noise of AC power supplied to other electrical appliances through a contact portion, and also indirectly saves power by absorbing in parallel harmonics and thermal noise of AC power supplied to other electrical appliances through a contact portion of a plug insertion portion of another wall-mounted outlet that shares AC power supplied from the distribution board or branch board is illustrated. A person having ordinary skill in the art to which the present invention pertains may infer various implementation methods (e.g., implementation methods in which some steps are omitted or the order is changed) for the above-described manufacturing process by referring to and/or modifying this Drawing 3. However, the present invention includes all of the inferred implementation methods, and its technical features are not limited only to the implementation methods illustrated in this Drawing 3.

Referring to Drawing 3, to produce an oxide mixture (140), raw materials containing N designated substances in a designated weight percentage (wt(%)) range are prepared (300), and the prepared raw materials are mixed and ground through a grinder while stirring to produce a mixed powder (305).

According to the first mixture manufacturing example of the present invention, after preparing raw materials manufactured for each of N designated materials to manufacture a mixed powder (300), the prepared raw materials for each material are mixed at a mixing ratio corresponding to a designated weight percentage range and ground to a size of 100 mesh to 200 mesh using a grinder while stirring to produce a mixed powder (305).

According to the second mixture manufacturing embodiment of the present invention, after preparing n (1 ≤ n ≤ N) ore raw materials containing N designated substances to manufacture a mixed powder (300), the prepared n ore raw materials are mixed at a mixing ratio corresponding to a designated weight percentage range based on the weight percentage of each substance contained in each of the n ore raw materials, and are ground to a size of 100 mesh to 200 mesh using a grinder while stirring to produce a mixed powder (305).

According to a third mixture manufacturing embodiment of the present invention, in order to manufacture a mixed powder, i (1 ≤ i ≤ N) ore raw materials containing at least some of N designated substances are prepared, and j (1 ≤ j ≤ N, N = i ∪ j) material-specific raw materials that are not included in the i ore raw materials among the N designated substances or are included in the i ore raw materials but are insufficient to match the designated weight percentage range are prepared (300), and then, based on the weight percentages of each substance included in the i ore raw materials, the prepared i ore raw materials and j material-specific raw materials are mixed at a mixing ratio corresponding to the designated weight percentage range and ground to a size of 100 mesh to 200 mesh through a grinder while stirring to produce a mixed powder (305).

According to the fourth mixture manufacturing embodiment of the present invention, in order to manufacture a mixed powder, k (1 ≤ k ≤ N) waste raw materials (e.g., waste sludge of solar panels generated in the process of manufacturing solar panels used for solar power generation, waste sludge of solar panels used for solar power generation and discarded, or oxide mixture (140) that has failed a quality inspection, etc.) containing at least some of N designated materials are prepared (300), and then the prepared k waste raw materials are mixed at a mixing ratio corresponding to a designated weight percentage range based on the weight percentage of each material included in the k waste raw materials, and are stirred while being ground to a size of 100 mesh to 200 mesh using a grinder to produce a mixed powder (305).

According to the fifth mixture manufacturing embodiment of the present invention, in order to manufacture a mixed powder, p (1 ≤ p ≤ N) waste raw materials (e.g., waste sludge from solar panels generated in the process of manufacturing solar panels used for solar power generation, waste sludge from solar panels used for solar power generation and discarded, or oxide mixture (140) that has failed a quality inspection, etc.) containing at least some of N designated substances are prepared, and q (1 ≤ q ≤ N, N = p∪q) material-specific raw materials that are not included in the p waste raw materials among the N designated substances or are included in the p waste raw materials but are insufficient to match the designated weight percentage range are prepared (300), and then, based on the weight percentages of each substance included in the p waste raw materials, the prepared p waste raw materials and q material-specific raw materials are mixed at a mixing ratio corresponding to the designated weight percentage range, and the mixture is ground to a size of 100 mesh to 200 mesh using a grinder while stirring to produce a mixed powder (305).

According to the sixth mixture manufacturing embodiment of the present invention, in order to manufacture a mixed powder, s (1 ≤ s ≤ N) ore raw materials and t (1 ≤ t ≤ N) waste raw materials containing at least some of N designated materials are prepared as raw materials, and u (1 ≤ u ≤ N, N = s∪ t ∪ u) material-specific raw materials that are not included in the s ore materials and t waste raw materials among the N designated materials or are included in the s ore materials and t waste raw materials but are insufficient to match the designated weight percentage range are prepared (300). Then, based on the weight percentages of the materials included in the s ore materials and the t waste raw materials, the prepared s ore materials, t waste raw materials, and u material-specific raw materials are mixed at a mixing ratio corresponding to the designated weight percentage range and ground to a size of 100 mesh to 200 mesh through a grinder while stirring to produce a mixed powder (305).

When the above mixed powder is produced, the mixed powder is placed in a low-temperature drying furnace, oxidized while supplying oxygen through dried air, and then cooled through nitrogen (N2) to produce an oxidized mixture stabilized in the air (310). Preferably, the mixed powder is oxidized for 45 hours or more through dried air at 80°C (10°C) in a low-temperature drying furnace to produce an oxidized mixture.

When the above-mentioned oxidation mixture is generated, the oxidation mixture is fired in an electric furnace at a temperature of 890°C to 970°C for 10 hours or more and cooled through nitrogen (N2) to generate a firing mixture (315).

When the above-mentioned sintered mixture is created, a specified binder and the above-mentioned sintered mixture are mixed in a preset mixing ratio and liquefied to create a liquid mixture (320).

In order to manufacture an oxide mixture (140) of a designated geometric structure, a first electrode part (145) and a second electrode part (145) made of a highly conductive metal material are arranged and fixed in a designated geometric relationship so as to be mutually insulated from each other on a frame manufactured with a designated geometric structure, and a power contact for electrically connecting to a designated terminal for power supply of the power plug part (105) is provided on one side of each electrode part (145), and a wiring contact for electrically connecting to a designated wiring part (130) is provided on the other side of each electrode part (145), and a manufacturing frame including an internal space for forming an external geometric structure capable of mounting or fixing the oxide mixture (140) in a designated mounting space formed in the body part (160) of the outlet device (100) is prepared (325).

When the above production mold is prepared, the liquefied liquid mixture is poured into the production mold, and the liquid mixture is placed in liquid contact with each electrode section (145) arranged in a designated geometric relationship, and dried at room temperature to solidify into a designated geometric structure corresponding to the mold (330).

If the liquid mixture is solidified to form the oxide mixture (140), the solidified oxide mixture (140) is separated from the production mold (335), and then a designated quality inspection (e.g., insulation inspection between electrode parts (145) arranged to be insulated from each other, breakdown inspection, etc.) is performed on the oxide mixture (140) (340).

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

Meanwhile, in case the quality inspection of the oxide mixture (140) is successful, the oxide mixture (140) is mounted or fixed in the mounting space formed inside the body (160) of the outlet device (100), and the first conductor (155) electrically connected to one terminal of the power plug (105) and the power contact provided in the first electrode portion (145) of the oxide mixture (140) are electrically connected, and at the same time, the other terminal of the power plug (105) and the first electrode portion (145) of the oxide mixture (140) are electrically connected to the power contact provided in the second electrode portion (145) which is arranged to be insulated by forming a designated geometric relationship with the first electrode portion (145) of the oxide mixture (140), and the first wiring portion (130) which electrically connects the M first contact portions (125) provided in the first terminal insertion hole (115) of one side of each of the M plug insertion portions (110) and the M first contact portions (125) provided in the first terminal insertion hole (115) of the M plug insertion portions (110) are electrically connected to the M first contact portions (125) provided in the first terminal insertion hole (115) of the M plug insertion portions (110) and the M first contact portions (125) provided in the oxide mixture (140) are electrically connected. The designated wiring contacts of the first electrode portion (145) are electrically connected, and at the same time, the second wiring portion (130) is electrically connected to the M second contact portions (125) provided in the second terminal insertion holes (115) on the other side of the M plug insertion portions (110), and the designated wiring contacts of the second electrode portion (145) provided in the oxide mixture (140) are electrically connected, and the operating module is mounted to manufacture the outlet device (100) (350).

100: Stand-alone outlet device 105: Power plug section
110: Plug insertion part 115: Terminal insertion hole
120: Grounding part 125: Contact part
130: Wiring section 135: Grounding section
140: Oxide mixture 145: Electrode
150: Switch section 155: Conductor section
160: Body 200: Operation module
205: Sensor unit 210: Processing unit
215: Generation Department 220: Communication Department
225: Power supply 230: Storage unit
235: Control unit 240: Output unit

Claims (34)

In a standing outlet device having a power plug for receiving AC power and M (M≥1) plug insertion portions for supplying AC power, and two terminal insertion holes of a designated structure formed at designated positions of the plug insertion portions,
An oxide mixture comprising a mixture of oxides in a mixed powder form, wherein N (N≥2) designated substances containing silicon (Si) and aluminum (Al) in a designated weight percentage (wt(%)) range are mixed at a predetermined mixing ratio, ground, and stirred, and a mixture of oxides in a mixed powder form is liquefied by mixing with a designated binder at a predetermined mixing ratio, and then the liquefied liquid mixture is injected into a frame having a geometric structure that can be installed inside the body of an outlet device while arranging an electrically conductive first electrode portion and a second electrode portion in a geometrically insulated manner in a designated geometrical relationship, and the liquid mixture is dried and solidified in a state where the first electrode portion and the second electrode portion are in liquid contact without any voids, so as to have dielectric properties, thermal conductivity, and electrical insulation corresponding to the oxide, and a oxide mixture that removes a designated resistance component on an electric line electrically connected to the first electrode portion and the second electrode portion in the form of heat energy;
A first conductor part electrically connecting a power contact provided in the first electrode part of the oxide mixture and one terminal of the power plug part;
A second conductor portion electrically connecting a power contact provided in a second electrode portion that is arranged to be insulated by forming a designated geometric relationship with the first electrode portion of the oxide mixture and the other terminal of the power plug portion;
A first wiring portion forming a wiring that electrically connects a designated wiring contact of a first electrode portion of the oxide mixture and M first contact portions provided in a first terminal insertion hole on one side of each of the M plug insertion portions;
A second wiring portion forming a wiring that electrically connects a designated wiring contact of a second electrode portion of the oxide mixture and M second contact portions provided in a second terminal insertion hole on a different side of each of the M plug insertion portions;
A processing unit that maintains an electrical connection state in which the first conductor part and the first wiring part are electrically connected to the first electrode part of the oxide mixture and the second conductor part and the second wiring part are electrically connected to the second electrode part of the oxide mixture, or temporarily releases the electrical connection state to switch to a direct power supply state in which power can be directly supplied from the first conductor part and the second conductor part to the first wiring part and the second wiring part, and then processes the electrical connection state to be restored;
A sensor unit that is electrically connected to the first wiring unit and the second wiring unit and senses a power-saving sensing value corresponding to the amount of power applied and used through the first electrode unit and the second electrode unit of the oxide mixture when the electrical connection state is maintained through the processing unit, and senses a non-power-saving sensing value corresponding to the amount of power applied and used directly to the first wiring unit and the second wiring unit in a state of electrical insulation from the first electrode unit and the second electrode unit of the oxide mixture when the electrical connection state is temporarily released;
A generation unit that generates designated processing information using at least one of the sensed power-saving sensing values and non-power-saving sensing values; and
It includes a communication unit that transmits a short-range wireless signal including the processing information or transmits the processing information to an app of a designated wireless terminal through a designated short-range wireless communication;
The above oxide mixture is connected in parallel with the power plug side through the first electrode section and the second electrode section within the body of the outlet device to save power by removing in parallel the resistance component on the external electric line including the electric line connected to the power plug side in a designated distribution board or distribution board, and at the same time, it is connected in series with each plug insertion section side to save power by removing in series the resistance component generated by the electric device that connects the internal electric line through each plug insertion section, and is characterized by a stationary outlet device having a short-range wireless communication function and an intuitive power saving function using a series-type oxide mixture.
In the first paragraph, the specified weight percentage range is:
Silicon (Si) in the range of 10 to 40 wt(%),
A stationary power outlet device having a short-range wireless communication function and an intuitive power-saving function using a serial oxide mixture, characterized in that it comprises aluminum (Al) in the range of 10 to 40 wt(%).
In the second paragraph, the sum of the weight percentages of silicon (Si) and aluminum (Al) is
A stationary power outlet device having a short-range wireless communication function characterized by a content of less than 60(+5) wt(%) and an intuitive power-saving function using a serial oxide mixture.
In the second paragraph, the N designated substances are
Iron (Fe) in the range of 5 to 20 wt(%),
A stationary power outlet device having a short-range wireless communication function and an intuitive power-saving function using a serial oxide mixture, characterized in that it further comprises at least one material in the range of 5 to 20 wt(%) of magnesium (Mg).
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