Patent application number | Description | Published |
20090148347 | NANO-CRYSTALLINE COMPOSITE-OXIDE THIN FILM, ENVIRONMENTAL GAS SENSOR USING THE THIN FILM, AND METHOD OF MANUFACTURING THE ENVIRONMENTAL GAS SENSOR - A nano-crystalline composite-oxide thin film for an environmental gas sensor, an environmental gas sensor using the thin film, and a method of manufacturing the environmental gas sensor are provided. The nano-crystalline composite-oxide thin film is formed of hetero-oxide nano-crystalline particles having independent crystalline phases from each other, and the environmental gas sensor including the thin film has excellent characteristics including high sensitivity, high selectivity, high stability and low power consumption. | 06-11-2009 |
20100126548 | THERMOELECTRIC DEVICE, THERMOELECTIC DEVICE MODULE, AND METHOD OF FORMING THE THERMOELECTRIC DEVICE - Provided are a thermoelectric device, a thermoelectric device module, and a method of forming the thermoelectric device. The thermoelectric device includes a first conductive type first semiconductor nanowire including at least one first barrier region; a second conductive type second semiconductor nanowire including at least one second barrier region; a first electrode connected to one end of the first semiconductor nanowire; a second electrode connected to one end of the second semiconductor nanowire; and a common electrode connected to the other end of the first semiconductor nanowire and the other end of the second semiconductor nanowire. The first barrier region is greater than the first semiconductor nanowire in thermal conductivity, and the second barrier region is greater than the second semiconductor nanowire in thermal conductivity. | 05-27-2010 |
20100133528 | CAPACITIVE GAS SENSOR AND METHOD OF FABRICATING THE SAME - A capacitive gas sensor and a method of fabricating the same are provided. The capacitive gas sensor includes an insulating substrate, a metal electrode and a micro thin-film heater wire integrally formed on the same plane of the insulating substrate, and an oxide detection layer coated on the metal electrode and the micro thin-film heater wire. The fabrication method includes depositing a metal layer on an insulating substrate, etching the metal layer so that a metal electrode and a micro thin-film heater wire form an interdigital transducer on the same plane, and forming a nano crystal complex oxide thin film or a complex oxide nano fiber coating layer on the metal electrode and the micro thin-film heater wire as a detecting layer. The capacitive gas sensor can be easily fabricated and can have excellent characteristics such as high sensitivity, high selectivity, high stability, and low power consumption. | 06-03-2010 |
20100155691 | METHOD OF FABRICATING SEMICONDUCTOR OXIDE NANOFIBERS FOR SENSOR AND GAS SENSOR USING THE SAME - A gas sensor for detecting environmentally harmful gases is provided. The sensor includes an insulating substrate, a metal electrode formed on the insulating substrate, and a sensing layer formed on the metal electrode and including a semiconductor oxide (La | 06-24-2010 |
20110031817 | RECTIFYING ANTENNA ARRAY - A rectifying antenna array includes a plurality of rectifying antennas connected in parallel. Each of the rectifying antennas includes a reception-side antenna receiving AC power through magnetic induction with a reception-side resonant antenna of a resonant wireless power receiver and a rectifier diode connected to the reception-side antenna and converting the AC power into DC power. | 02-10-2011 |
20110120866 | ENVIRONMENTAL GAS SENSOR AND METHOD OF MANUFACTURING THE SAME - Provided are an environmental gas sensor and a method of manufacturing the same. The environmental gas sensor includes an insulating substrate, metal electrodes formed on the insulating substrate, and a sensing layer in which different kinds of nanofibers are arranged perpendicular to each other on the metal electrodes. Thus, the environmental gas sensor can simultaneously sense two kinds of gases. | 05-26-2011 |
20110129668 | ORGANIC-INORGANIC HYBRID NANOFIBER FOR THERMOELECTRIC APPLICATION AND METHOD OF FORMING THE SAME - Provided is an organic-inorganic hybrid nanofiber including an inorganic semiconductor material in a nanoparticle or nanocrystal state, and a conductive polymer including the inorganic semiconductor material and having a lower thermal conductivity than the inorganic semiconductor material. The inorganic semiconductor material and the conductive polymer are arranged in a composite material type to have a thermoelectric property. Thus, the organic-inorganic hybrid nanofiber can be applied to a low-priced thermoelectric device having relatively high thermoelectric conversion efficiency. | 06-02-2011 |
20110133569 | WIRELESS POWER TRANSMISSION DEVICE AND WIRELESS POWER RECEPTION DEVICE - Provided are a wireless power transmission device and wireless power reception device. A power-relaying resonant coil is disposed between a power transmitter and a power receiver to increase transmission efficiency and lengthen a transmission distance. The wireless power transmission device includes a power generation module for generating power, a power coil for receiving the power, a transmitting coil for resonating at the unique resonant frequency due to magnetic induction with the power coil and generating a non-radiative electromagnetic wave, and one or more power relay coils for relaying the non-radiative electromagnetic wave. | 06-09-2011 |
20110140671 | PORTABLE DEVICE AND BATTERY CHARGING METHOD THEREOF - Provided is a portable device. The portable device includes a near distance antenna, a long distance antenna, a first power generation circuit, a second power generation circuit, and a battery. The near distance antenna receives a first power source signal in an electromagnetic inductive coupling scheme. The long distance antenna receives a second power source signal in a magnetic resonance scheme. The first power generation circuit generates a power source from the first power source signal. The second power generation circuit generates a power source from the second power source signal. The battery is charged with the generated power source. | 06-16-2011 |
20120025622 | WIRELESS POWER TRANSMITTER, WIRELESS POWER RECEIVER, AND METHOD FOR WIRELESS POWER TRANSFER USING THEM - Provided is a method for a wireless power transfer. The method includes modulating a transmission frequency according to a predetermined value at a wireless power transmitter; and transmitting a high frequency signal according to the modulated transmission signal from the wireless power transmitter to at least one wireless power receiver and redetermining the predetermined value according to information which corresponds to a power value of the high frequency signal received by the at least one wireless power receiver, wherein the modulating the transmission frequency at the wireless power transmitter and transmitting the high frequency and the redetermining the predetermined value the at least one wireless power receiver are repeated. | 02-02-2012 |
20120152296 | THERMOELECTRIC DEVICE, THERMOELECTIC DEVICE MODULE, AND METHOD OF FORMING THE THERMOELECTRIC DEVICE - Provided are a thermoelectric device, a thermoelectric device module, and a method of forming the thermoelectric device. The thermoelectric device includes a first conductive type first semiconductor nanowire including at least one first barrier region; a second conductive type second semiconductor nanowire including at least one second barrier region; a first electrode connected to one end of the first semiconductor nanowire; a second electrode connected to one end of the second semiconductor nanowire; and a common electrode connected to the other end of the first semiconductor nanowire and the other end of the second semiconductor nanowire. The first barrier region is greater than the first semiconductor nanowire in thermal conductivity, and the second barrier region is greater than the second semiconductor nanowire in thermal conductivity. | 06-21-2012 |