The present invention provides a degradable and recyclable epoxy conductive adhesive, which comprises the following raw materials in percentage by weight: 15% to 30% of epoxy resin, 1% to 10% of a curing agent, 0.1% to 2% of a reaction diluent and 15% to 85% of a conductive filler, wherein the curing agent comprises a breakable molecular structure. According to the epoxy conductive adhesive of the present invention, after the epoxy resin in the conductive adhesive is cured by using the recyclable and degradable epoxy resin curing agent of a specific molecular structure, the conductive adhesive can be degraded in normal pressure, mild and specific conditions, the process is simple and the operation is convenient, no contamination is brought to the environment, the recycling cost is largely reduced, and the recycling of the conductive adhesive has enormous economic and environmental advantages. By using the recyclable and degradable epoxy resin curing agent of a specific molecular structure, the shear strength of the conductive adhesive is greatly increased, and the reliability and the service life of the conductive adhesive are largely improved.

The object of the present invention is to provide a method of producing oxide particles, which can improve crystallinity of the obtained oxide particles, more desirably can form single crystal oxide particles stably. The present invention provides a method of producing oxide particles, which comprises at least two fluids to be processed including the first fluid and the second fluid, wherein one of the first fluid and the second fluid is an oxide raw material liquid obtained by mixing at least an oxide particle raw material with a solvent, and the other of the first fluid and the second fluid is an oxide precipitation solvent obtained by mixing at least a basic substance with a solvent, and wherein the method comprises mixing the first fluid and the second fluid in the space between the processing surfaces which are disposed so as to face each other, being capable of approaching to and separating from each other, at least one of which rotates relatively to the other; and discharging the mixed fluid in which the oxide particles are precipitated from the space between the processing surfaces; and wherein the method controls crystallinity of the oxide particles discharged from the space between the processing surfaces, by changing at least one selected from the group consisting of the temperature of the first fluid to be introduced in the space between the processing surfaces, the temperature of the second fluid to be introduced in the space between the processing surfaces, and the temperature of the first fluid and the second fluid at the time of mixing.

The ozone cleaning device contains an electrically conductive member and a reinforced casing member. The casing member is injection-molded and houses the conductive member inside in an airtight manner. The reinforcement of the casing member, and the tight integration between the casing member and the conductive member jointly achieve enhanced structural strength to prevent the ozone cleaning device from being broken. When the ozone cleaning device is held close to a user and an electrical power is delivered to the conductive member, the conductive member is then conducting to the user and the air in between is influenced by the electrical power to produce ozone for cleaning. The present invention therefore achieves enhanced structural strength, usage safety, and prolonged operational life.

The ozone cleaning device contains an electrically conductive member and a reinforced casing member. The casing member is injection-molded and houses the conductive member inside in an airtight manner. The reinforcement of the casing member, and the tight integration between the casing member and the conductive member jointly achieve enhanced structural strength to prevent the ozone cleaning device from being broken. When the ozone cleaning device is held close to a user and an electrical power is delivered to the conductive member, the conductive member is then conducting to the user and the air in between is influenced by the electrical power to produce ozone for cleaning. The present invention therefore achieves enhanced structural strength, usage safety, and prolonged operational life.

A method includes: storing a first flow rate from an oxygen mass flow controller for supplying an oxygen with an ozone generator turned off and measuring a flow rate of the oxygen supplied to the ozone generator, and a second flow rate from at least one ozone mass flow controller provided in flow paths; supplying the ozone into a processing container via the flow paths to perform multiple times a predetermined ozone-based process; acquiring a third flow rate from the oxygen mass flow controller and a fourth flow rate from the at least one ozone mass flow controller, by supplying the oxygen with the ozone generator turned off during a predetermined period between the ozone-based processes; and determining whether the fourth flow rate is a normal value by comparing the first and second flow rates with the third and fourth flow rates, respectively.

The use of gaseous oxygen for the production of a therapeutic gas for inhalation by a patient who has been identified as a person with a mitochondrial disorder or a coenzyme Q10 deficiency, for the treatment of mitochondrial disorders or Q10 deficiencies is disclosed. For the first time a non-invasive method is disclosed, upon what the body's own level of Q10 can be raised significantly without further interventions.

A pressure sensor and a manufacturing method thereof are provided. The pressure sensor includes a thin-film transistor (TFT) array and a pressure-sensitive layer covering the TFT array. The pressure-sensitive layer includes a plurality of insulating layers and one of one-dimensional materials arranged on the same plane and two-dimensional materials. The insulating layers and the one- or two-dimensional materials are alternately stacked so as to effectively enhance pressure resolution.

A pressure sensor and a manufacturing method thereof are provided. The pressure sensor includes a thin-film transistor (TFT) array and a pressure-sensitive layer covering the TFT array. The pressure-sensitive layer includes a plurality of insulating layers and one of one-dimensional materials arranged on the same plane and two-dimensional materials. The insulating layers and the one- or two-dimensional materials are alternately stacked so as to effectively enhance pressure resolution.

An oxygen allotrope generator having a tube with an electrically grounded outer surface and an electrically positive inner surface. A plurality of corona reaction plates are spaced along the interior of the tube, the plates being longitudinally inter-connected by wires and being in electrical connection with the electrically positive inner surface of the tube. An outer jacket encloses the tube and provides a second linear pass for partially ozonated gas to flow in the generator. An alternative embodiment includes external distributed ground connections at the locations of the corona reaction.

An oxygen allotrope generator having a tube with an electrically grounded outer surface and an electrically positive inner surface. A plurality of corona reaction plates are spaced along the interior of the tube, the plates being longitudinally inter-connected by wires and being in electrical connection with the electrically positive inner surface of the tube. An outer jacket encloses the tube and provides a second linear pass for partially ozonated gas to flow in the generator. An alternative embodiment includes external distributed ground connections at the locations of the corona reaction.