Abstract: Provided is a power conversion system. The system includes a DC bus line including a common terminal, a power generation device configured to provide DC power to the common terminal, a first inverter configured to convert a first input power provided from the common terminal into a first AC power and output the first AC power, and a second inverter configured to convert a second input power provided from the common terminal into a second AC power in response to the first input power being greater than a first threshold power while the first inverter operates and output the second AC power.

Abstract: Provided is a power conversion system. The system includes a DC bus line including a common terminal, a power generation device configured to provide DC power to the common terminal, a first inverter configured to convert a first input power provided from the common terminal into a first AC power and output the first AC power, and a second inverter configured to convert a second input power provided from the common terminal into a second AC power in response to the first input power being greater than a first threshold power while the first inverter operates and output the second AC power.

Abstract: Provided is an inverter system capable of more economically and efficiently performing photovoltaic power generation by automatically switching an integrated operation and an independent operation of inverters according to voltage values and current values of photovoltaic panels without a separate communication function. The inverter system for photovoltaic power generation according to an exemplary embodiment of the present disclosure is an inverter system which changes direct current power output from a first photovoltaic panel and a second photovoltaic panel to alternating current power and includes: a first inverter and a second inverter, in which all of the outputs of the first and second photovoltaic panels are applied to the first inverter, or the output of the first photovoltaic panel is applied to the first inverter, and the output of the second photovoltaic panel is applied to the second inverter according to output values of the first and second photovoltaic panels.

Abstract: Provided are a method of manufacturing a metal oxide and a substrate for a solar cell. The method of manufacturing the metal oxide according to the inventive concept includes mixing a metal precursor material, a basic material, amphiphilic molecules and distilled water to prepare a metal precursor solution, performing a first heat treatment with the metal precursor solution to form a metal oxide, and performing a second heat treatment with the metal oxide to form a pair of metal oxide disks having a single crystalline structure. A pair of zinc oxide disks includes a first disk, and a second disk separated from the first disk in a perpendicular direction to the first disk.

Abstract: A method of fabricating a metal oxide sheet having a polycrystalline structure includes mixing a metal precursor material, a base material, and distilled water with each other to fabricate a preparation solution; adding an anionic surfactant into the preparation solution to forming a precursor solution; forming metal oxide nanoparticles in the precursor solution, wherein each of the metal oxide nanoparticles comprises a metal cation and an oxygen anion; and fabricating a metal oxide sheet by coupling the metal oxide nanoparticles to each other, wherein, in an aspect of a plane, the metal oxide sheet has a hexagonal shape and a polycrystalline structure.

Abstract: Provided are an electrolyte for a dye-sensitized solar cell and a dye-sensitized solar cell including the same. The electrolyte for a dye-sensitized solar cell includes an organic solvent, a metal anion compound, and a quaternary ammonium salt compound (R4N+X?). X? and Y? are multi-redox systems which are in chemical equilibrium.

Abstract: Provided is a method of fabricating metal oxide. The method includes mixing a metal precursor material, a base material, and distilled water with each other to fabricate a preparation solution, adding an anionic surfactant into the preparation solution to forming a precursor solution, forming metal oxide nanoparticles in the precursor solution, and fabricating a metal oxide sheet by coupling the metal oxide nanoparticles to each other. The polycrystalline metal oxide may have a sheet or nanowire shape.

Abstract: Provided are a dye-sensitized solar cell and a method of manufacturing the same. The dye-sensitized solar cell includes a lower substrate, an upper substrate opposite to the lower substrate, an electrolyte between the upper substrate and the lower substrate, a sealing member surrounding edges of the upper substrate and the lower substrate and including a plurality of openings for providing a space between the upper substrate and the lower substrate with the electrolyte, and a plurality of plugs inserted in the openings.

Abstract: Provided are a method of manufacturing a metal oxide and a substrate for a solar cell. The method of manufacturing the metal oxide according to the inventive concept includes mixing a metal precursor material, a basic material, amphiphilic molecules and distilled water to prepare a metal precursor solution, performing a first heat treatment with the metal precursor solution to form a metal oxide, and performing a second heat treatment with the metal oxide to form a pair of metal oxide disks having a single crystalline structure. A pair of zinc oxide disks includes a first disk, and a second disk separated from the first disk in a perpendicular direction to the first disk.

Abstract: Disclosed are a method of manufacturing a dye sensitized solar battery and a solar battery assembling apparatus. The method includes: forming electrode pads on electrodes of respective solar battery sub modules; applying a conductive adhesive on the electrode; and overlapping the electrodes of the solar battery sub modules, applying a current to the electrode pads, and then heating and hardening the conductive adhesive.

Abstract: A method of fabricating a transparent electrode includes preparing conductive nanoparticles, preparing a metal oxide sol, mixing and reacting the conductive nanoparticles with the metal oxide sol to form a metal oxide solution including a metal oxide combined with the conductive nanoparticles, coating the metal oxide solution on a substrate, and performing an annealing process on the coated metal oxide solution.

Abstract: Provided are a method of forming metal oxide nanotube and a dye-sensitized solar cell formed thereby. The method may include providing a metal electrode and a counter electrode in an electrolyte containing a negatively polarized surfactant, and applying voltages to the metal electrode and the counter electrode to form a metal oxide nanotube on the metal electrode. The metal oxide nanotube may have a (001)-plane.

Abstract: Provided is a sensing device having a multi beam antenna array. The sensing device includes an antenna array including a plurality of antennas, a plurality of low noise amplifiers respectively connected to the antennas to amplify radio frequency signals received from the respective antennas, a delay line box including a plurality of delay lines, each delay line delaying the signals amplified by the low noise amplifiers for a predetermined time, and a detector detecting the output signals of the delay ling box.

Abstract: Provided is an inverter system capable of more economically and efficiently performing photovoltaic power generation by automatically switching an integrated operation and an independent operation of inverters according to voltage values and current values of photovoltaic panels without a separate communication function. The inverter system for photovoltaic power generation according to an exemplary embodiment of the present disclosure is an inverter system which changes direct current power output from a first photovoltaic panel and a second photovoltaic panel to alternating current power and includes: a first inverter and a second inverter, in which all of the outputs of the first and second photovoltaic panels are applied to the first inverter, or the output of the first photovoltaic panel is applied to the first inverter, and the output of the second photovoltaic panel is applied to the second inverter according to output values of the first and second photovoltaic panels.

Abstract: Provided is a solid type heat dissipation device for electronic communication appliances. The solid type heat dissipation device includes a graphite thin plate horizontally transferring heat, a plurality of metal fillers passing through the graphite thin plate to vertically transfer heat, and a plurality of metal thin plates attached to upper and lower surfaces of the graphite thin plate and connected to the metal fillers.

Abstract: A sensing device may include an antenna. The antenna may include a top wafer and a bottom wafer coupled to the top wafer. The antenna may further include an air cavity between the top wafer and the bottom wafer. The sensing device may further include a substrate and an interposer disposed between the antenna and the substrate.

Abstract: Provided are a solar cell and a method of fabricating the same. The solar cell may include a first electrode including a first substrate attached with a first transparent conductive film and a metal oxide nanotube provided on the first substrate and adsorbed with a dye, a second electrode facing the first electrode, and an electrolyte filling between the first and second electrodes. In example embodiments, metal nanoparticles may be provided on an inner surface of the metal oxide nanotube.

Abstract: Disclosed is a method for manufacturing a dye sensitized solar cell module. The method includes putting at least one or more heating-wires on an upper portion of an electrode of each solar cell sub-module; applying a metal paste on the upper portion of the electrode including at least one or more heating-wires; and heating and curing the metal paste by after overlapping the electrodes of a plurality of solar cell sub-modules each other, allowing a current to flow to at least one or more heating-wires.

Abstract: Provided is a solar cell module. The solar cell module includes a solar cell, a sealing layer configured to protect the solar cell, and a bonding layer disposed between the solar cell and the sealing layer. The bonding layer has adhesion to fix the sealing layer to the solar cell. When the sealing layer is repaired, the adhesion of the bonding layer is reduced by an external stimulation.

Abstract: Provided is an electronic device that includes an LTCC inductor including a first sheet disposed on a substrate and including a first conductive pattern, a second sheet disposed on the first sheet and including a second conductive pattern, and a via electrically connecting the first conductive pattern to the second conductive pattern, and a spacer disposed on a lower surface of the first sheet to provide an air gap between the substrate and the first sheet, wherein the first conductive pattern is exposed out of the lower surface of the first sheet.