Patent application number | Description | Published |
20100282968 | Device and method for terahertz imaging with combining terahertz technology and amplitude-division interference technology - This invention provides a device and a method for THz imaging to obtain real 3D image of sample and achieve high resolution, by combining THz technology and amplitude-division interference technology. | 11-11-2010 |
20100289367 | PERMANENT MAGNET ROTOR - A permanent magnet rotor comprising a shaft, a rotor core fixed to the shaft, a magnet disposed around the core, and a linker fixed relative to the shaft and located at one end of the core; wherein an elastic clamping structure is arranged between the linker and the magnet such that rotational torque of the magnet can be transferred to the shaft via the linker. | 11-18-2010 |
20110093614 | METHOD AND DEVICE FOR DUPLICATING MULTICAST PACKETS - A message sending method is provided, which includes: obtaining route feature information of a user, and sending a request of the user, where the request is data in an Efficient Extensible Markup Language (XML) Interchange (EXI) format, and the route feature information is carried in a header of the data in the EXI format. A message processing method, a client, a router, and a message processing system are further provided. Through preceding technical solutions, a user request message is routed according to route feature information in an EXI header, thereby reducing a system overhead and improving a distribution processing efficiency. | 04-21-2011 |
20110159849 | Method, Device, and Mobile Terminal for Controlling Locking and Unlocking - A method, a device, and a mobile terminal for controlling locking and unlocking are provided. The method includes the following steps. An acceleration sensor is adopted to detect a location state of a mobile terminal. A stabilization timer is started and a stabilization timing value of the stabilization timer is monitored when the mobile terminal is in an unlocked or a locked state. The stabilization timing value is reset to restart timing when it is monitored that the location state of the mobile terminal is unstable. The mobile terminal is controlled to enter a stable and unlocked state when it is monitored that the stabilization timing value reaches a stabilization timing threshold. Through the technical solutions, it is determined whether the mobile terminal enters the stable and unlocked state according to the location state of the mobile terminal in the locked or unlocked state. In this manner, the mobile terminal may not be locked in the stable state, and the afterward operations may be facilitated, thereby increasing usability of the mobile terminal and improving user's experience. | 06-30-2011 |
20120304823 | METHOD FOR PREPARING SPONGE TITANIUM FROM POTASSIUM FLUOTITANATE BY ALUMINOTHERMIC REDUCTION - The invention provides a method for preparing sponge titanium from potassium fluotitanate by aluminothermic reduction, comprising the following steps: a reaction step: aluminum and zinc are mixed under a vacuum state, and the mixture is then reacted with potassium fluotitanate; a distillation step: KF, AlF | 12-06-2012 |
20120304824 | TECHNOLOGICAL METHOD FOR PREPARING SPONGE TITANIUM FROM SODIUM FLUOTITANATE RAW MATERIAL - The invention provides a technological method for preparing sponge titanium from sodium fluotitanate raw material, comprising the following steps: step A: placing aluminum in an airtight resistance furnace, evacuating, introducing inert gas into the resistance furnace, and heating the aluminum to obtain molten aluminum; step B: opening a reactor cover, adding a proper amount of sodium fluotitanate into the reactor, closing the reactor cover, detecting leakage, slowly heating the reactor to 150° C., evacuating and continuously heating the reactor to 250° C.; step C: introducing inert gas into the reactor, continuously heating the reactor to 900° C., and stirring uniformly; step D: opening a valve, adjusting the stirring speed, dripping the molten aluminum, and controlling the temperature of reaction in a range from 900 to 1000° C.; and step E: opening the reactor cover, removing a stirring device out of the reactor, and eliminating NaAlF | 12-06-2012 |
20120304825 | PROCESS FOR PRODUCING SPONGE TITANIUM - The present invention provides a process for producing sponge titanium, which includes the following steps: Step A: placing aluminum into a resistance furnace, vacuum pumping, introducing inert gas, heating to molten aluminum; Step B: opening a reactor cover, adding a proper amount of potassium fluotitanate to a reactor, leakage detecting after closing the reactor cover, slowly raising the temperature to 150° C., vacuum pumping, and continuously heating to 250° C.; Step C: introducing inert gas into the reactor, continuously raising the temperature to 750° C., stirring uniformly; Step D: opening a valve to adjust the stirring speed, adding molten aluminum drops, and controlling the reaction temperature to 750° C. to 850° C.; Step E: opening the reactor cover, removing a stirring device, eliminating the upper layer of KAlF | 12-06-2012 |
20120304826 | METHOD FOR PREPARING SPONGE TITANIUM FROM SODIUM FLUOTITANATE BY ALUMINOTHERMIC REDUCTION - The invention provides a method for preparing sponge titanium from sodium fluotitanate by aluminothermic reduction, comprising the following steps: a reaction step: aluminum and zinc are mixed under a vacuum state, and sodium fluotitanate is then added into the mixture for reaction; a separation step: the product resulting from the complete reaction stands still and is then introduced with inert gas, and NaF and AlF | 12-06-2012 |
20120321522 | ZERO POLLUTION RECOVERY SYSTEM FOR SAFELY PRODUCING ANHYDROUS FLUORINE HYDRIDE - The present invention provides a zero pollution recovery system for safely producing anhydrous fluorine hydride, comprising: a compartment, a reactor for producing fluorine hydride, and a water pool; the reactor is disposed in the compartment; the water pool is disposed at the bottom of the compartment; absorption hoods are respectively disposed above both ends of the reactor for absorbing fluorine hydride gas; at least two absorption towers mutually connected in series via pipes are disposed above the compartment; water pipes connected with the water pool are respectively disposed at the top and bottom of the absorption tower; and a cooler and a receiver connected with the water pool is disposed on the pipes. The present invention has the advantages of being able to control the range over which fluorine hydride can diffuse. | 12-20-2012 |
20130091988 | METHOD FOR PRODUCING METAL ZIRCONIUM INDUSTRIALLY AND PRODUCING LOW-TEMPERATURE ALUMINUM ELECTROLYTE AS BYPRODUCT - The invention provides a preparation method for producing metal zirconium industrially and producing low-temperature aluminum electrolyte as byproduct, which comprises the following steps: A) aluminum and fluorozirconate are put in a closed reactor, inert gas is fed into the reactor after evacuation, the reactor is heated up to 780° C. to 1000° C. and then the mixture in the reactor is stirred rapidly; and B) after reaction continues for 4 to 6 hours, the liquid molten at the upper layer is sucked out to obtain low-temperature aluminum electrolyte, and the product at the lower layer is subjected to acid dipping or distillation to remove surface residue to obtain metal zirconium. | 04-18-2013 |
20130092550 | LOW-MOLECULAR-RATIO CRYOLITE FOR ALUMINIUM ELECTROLYTIC INDUSTRY AND METHOD FOR PREPARING THE SAME - The disclosure provides low-molecular-ratio cryolite for aluminium electrolytic industry, which consists of potassium cryolite and sodium cryolite with a mole ratio of 1:1˜1:3, wherein the molecular formula of the potassium cryolite is mKF.AlF | 04-18-2013 |
20130092551 | ELECTROLYTE SUPPLEMENT SYSTEM IN ALUMINIUM ELECTROLYSIS PROCESS AND METHOD FOR PREPARING THE SAME - The disclosure provides an electrolyte supplement system in an aluminium electrolysis process, which includes low-molecular-ratio cryolite, wherein the low-molecular-ratio cryolite is selected from mKF.AlF | 04-18-2013 |
20130092552 | POTASSIUM CRYOLITE FOR ALUMINUM ELECTROLYSIS INDUSTRY AND PREPARATION METHOD THEREOF - The invention provides a potassium cryolite for aluminum electrolysis industry, which has a molecular formula: mKF.AlF | 04-18-2013 |
20130095020 | CYCLIC PREPARATION METHOD FOR PRODUCING TITANIUM BORIDE FROM INTERMEDIATE FEEDSTOCK SODIUM-BASED TITANIUM-BORON-FLUORINE SALT MIXTURE AND PRODUCING SODIUM CRYOLITE AS BYPRODUCT - A cyclic preparation method for producing titanium boride from intermediate feedstock sodium-based titanium-boron-fluorine salt mixture and producing sodium cryolite as byproduct, which comprises the steps: a) boric acid or boric anhydride is added with hydrofluoric acid and then with sodium carbonate solution for concentration and crystallization to generate sodium fluoborate; titanium-iron concentrate is added with hydrofluoric acid and then with sodium carbonate and sodium hydroxide to obtain sodium fluotitanate; B) the sodium fluoborate is mixed with the sodium fluotitanate, and the mixture reacts with aluminum to generate titanium boride and sodium cryolite; C) the sodium cryolite is sucked out and then fed into a rotary reaction kettle together with concentrated sulfuric acid, hydrogen fluoride gas as well as sodium sulfate and sodium aluminum sulfate are generated by reaction in the rotary reaction kettle, and the hydrogen fluoride gas is collected and then dissolved in water to obtain hydrofluoric acid aqueous solution; and D) the obtained hydrofluoric acid aqueous solution is recycled. | 04-18-2013 |
20130095021 | CYCLIC PREPARATION METHOD FOR PRODUCING TITANIUM BORIDE FROM INTERMEDIATE FEEDSTOCK POTASSIUM-BASED TITANIUM-BORON-FLUORINE SALT MIXTURE AND PRODUCING POTASSIUM CRYOLITE AS BYPRODUCT - A cyclic preparation method including the following steps: a) boric acid or boric anhydride is added with hydrofluoric acid and then with potassium sulfate for reaction to generate potassium fluoborate; titanium-iron concentrate is added with hydrofluoric acid and then with potassium sulfate for reaction to generate potassium fluotitanate; B) the potassium fluoborate is mixed with the potassium fluotitanate, and the mixture reacts with aluminum to generate titanium boride and potassium cryolite; C) the potassium cryolite is sucked out and then fed into a rotary reaction kettle together with concentrated sulfuric acid, hydrogen fluoride gas as well as potassium sulfate and potassium aluminum sulfate are generated by reaction in the rotary reaction kettle, and the hydrogen fluoride gas is collected and then dissolved in water to obtain hydrofluoric acid aqueous solution; and D) the obtained hydrofluoric acid aqueous solution and potassium sulfate aqueous solution are recycled. | 04-18-2013 |
20130095022 | PREPARATION PROCESS OF TRANSITION METAL BORIDE AND USES THEREOF - The invention provides a preparation process of transition metal boride, comprising the following steps: A) aluminum is put in a reactor, inert gas is fed into the reactor after evacuation, the reactor is heated up to 700 to 800° C. and then added with dry potassium fluoborate or sodium fluoborate, monomer boron and cryolite are generated by rapid stirring and reaction for 4 to 6 hours, and the molten liquid at the upper layer is sucked out and the monomer boron is obtained by means of separation; and B) the obtained monomer boron is added with transition metal for reaction at the temperature from 1800 to 2200° C. in order to generate corresponding transition metal boride. | 04-18-2013 |
20130095023 | METHOD FOR CYCLICALLY PREPARING MONOMER BORON AND COPRODUCING POTASSIUM CRYOLITE USING POTASSIUM FLUOBORATE AS INTERMEDIATE MATERIAL - A method for cyclically preparing monomer boron and coproducing potassium cryolite using potassium fluoborate as an intermediate material, which includes following steps: A) adding hydrofluoric acid to boric acid or boron oxide to enable a reaction to form fluoboric acid; B) adding a potassium sulphate aqueous solution to the fluoboric acid to enable a reaction to form the potassium fluoborate; C) putting the potassium fluoborate into a reactor, adding aluminium to react with the potassium fluoborate to form the monomer boron and potassium cryolite; D) extracting the potassium cryolite, sending the potassium cryolite to a rotary reaction kettle together with concentrated sulphuric acid to enable a reaction to form hydrogen fluoride gas and aluminium potassium sulphate, potassium sulphate, collecting the hydrogen fluoride gas and dissolving it into water to obtain the hydrofluoric acid; E) recycling the obtained hydrofluoric acid to Step A to leach the boric acid or boron oxide. | 04-18-2013 |
20130095024 | METHOD FOR CYCLICALLY PREPARING MONOMER BORON AND COPRODUCING SODIUM CRYOLITE USING SODIUM FLUOBORATE AS INTERMEDIATE MATERIAL - A method for cyclically preparing monomer boron and coproducing sodium cryolite using sodium fluoborate as an intermediate material, which includes the following steps: A) adding hydrofluoric acid to boric acid or boron oxide to enable a reaction to form fluoboric acid; B) adding a sodium carbonate aqueous solution to the fluoboric acid to enable a reaction to form the sodium fluoborate; C) putting the sodium fluoborate into a reactor, adding aluminium to react with the sodium fluoborate to form the monomer boron and sodium cryolite; D) extracting the sodium cryolite, sending the sodium cryolite to a rotary reaction kettle together with concentrated sulphuric acid to enable a reaction to form hydrogen fluoride gas and aluminium sodium sulphate, collecting the hydrogen fluoride gas and dissolving it into water to obtain the hydrofluoric acid; E) recycling the obtained hydrofluoric acid to Step A to leach the boric acid or boron oxide. | 04-18-2013 |
20130098206 | METHOD FOR CYCLICALLY PREPARING TITANIUM SPONGE AND COPRODUCING SODIUM CRYOLITE USING SODIUM FLUOTITANATE AS INTERMEDIATE MATERIAL - A method for cyclically preparing titanium sponge and coproducing sodium cryolite using sodium fluotitanate as an intermediate material, which includes the following steps: A) adding hydrofluoric acid to titaniferous iron concentrate to enable a reaction to form fluotitanic acid; B) adding sodium carbonate and sodium hydroxide to the fluotitanic acid to enable a reaction to form the sodium fluotitanate; C) putting the sodium fluotitanate into a reactor, adding aluminium to react with the sodium fluotitanate to form the titanium sponge and sodium cryolite; D) extracting the sodium cryolite and sending it to a rotary reaction kettle together with concentrated sulphuric acid to enable a reaction to form hydrogen fluoride gas and sodium sulphate, aluminium sodium sulphate; collecting the hydrogen fluoride gas and dissolving it into water to obtain a hydrofluoric acid solution; E) recycling the obtained hydrofluoric acid to Step A to leach the titaniferous iron concentrate. | 04-25-2013 |
20130098207 | METHOD FOR CYCLICALLY PREPARING TITANIUM SPONGE AND COPRODUCING POTASSIUM CRYOLITE USING POTASSIUM FLUOTITANATE AS INTERMEDIATE MATERIAL - A method for cyclically preparing titanium sponge and coproducing potassium cryolite using potassium fluotitanate as an intermediate material, which includes the following steps: A) adding hydrofluoric acid to titaniferous iron concentrate to enable a reaction to form fluotitanic acid; B) adding potassium sulphate to the fluotitanic acid to enable a reaction to form the potassium fluotitanate; C) putting the potassium fluotitanate into a reactor, adding aluminium to react with the potassium fluotitanate to form the titanium sponge and potassium cryolite; D) extracting the potassium cryolite and sending it to a rotary reaction kettle together with concentrated sulphuric acid to enable a reaction to form hydrogen fluoride gas and potassium sulphate, aluminium potassium sulphate; collecting the hydrogen fluoride gas and dissolving it into water to obtain a hydrofluoric acid aqueous solution; E) recycling the obtained hydrofluoric acid aqueous solution to Step A to leach the titaniferous iron concentrate. | 04-25-2013 |
20130115370 | PROCESS FOR PREPARING INERT ANODE MATERIAL OR INERT CATHODE COATING MATERIAL FOR ALUMINIUM ELECTROLYSIS - The disclosure provides a process for preparing an inert anode material or inert cathode coating material for aluminium electrolysis, which includes the following steps: A) putting aluminium into a reactor, injecting an inert gas to the reactor after vacuumizing, adding the mixture of dried fluoborate and fluorotitanate in the reactor to enable a reaction to form titanium boride and cryolite, and isolating the titanium boride; and B) melting the obtained titanium boride with a carbon material, tamping the melt liquid on a carbon cathode surface, sintering the carbon cathode surface to form the inert cathode coating material for aluminium electrolysis; or, mixing the obtained titanium boride with the carbon material evenly, then high-pressure moulding the mixture, and finally sintering the moulded mixture at a high temperature to form the inert anode material for aluminium electrolysis. | 05-09-2013 |
20140055957 | Composite Material and Electronic Device - A composite material and an electronic device are disclosed in embodiments of the present invention, relating to the field of electronic assembly technologies. The technical problem of the existing electronic device with an excessively complicated internal structure is solved. The composite material includes an electrically and thermally conductive layer, a viscose glue layer, and an insulating layer, where the electrically and thermally conductive layer and the insulating layer are pasted at two sides of the viscose glue layer; the viscose glue layer is electrically conductive. The electronic device includes a circuit board and the composite material. Gaps are formed at the insulating layer in positions corresponding to electronic components and/or shielding frames, with the viscose glue layer exposed, the composite material is pasted onto the electronic components and/or the shielding frames via the viscose glue layer. The present invention is applied to simplify the structure of an electronic device. | 02-27-2014 |
20140102678 | Apparatus with Heat Insulation Structure - Embodiments of the present invention provide an apparatus with a heat insulation structure, where the apparatus includes an object to be heat-insulated and also includes a heat insulation closed layer disposed between the object to be heat-insulated and a heat source. The heat insulation structure adopted in the present invention specifically is a heat insulation closed layer, where the heat insulation closed layer performs heat insulation protection through a closed space between the object to be heat-insulated and the heat source, rather than performing heat insulation mainly through a physical material with a small heat conduction coefficient. | 04-17-2014 |
20140131214 | LOW-MOLECULAR-RATIO CRYOLITE FOR ALUMINIUM ELECTROLYTIC INDUSTRY AND METHOD FOR PREPARING THE SAME - The disclosure provides low-molecular-ratio cryolite for aluminum electrolytic industry, which consists of potassium cryolite and sodium cryolite with a mole ratio of 1:1˜1:3, wherein the molecular formula of the potassium cryolite is mKF.AlF | 05-15-2014 |
20140131215 | ELECTROLYTE SUPPLEMENT SYSTEM IN ALUMINIUM ELECTROLYSIS PROCESS AND METHOD FOR PREPARING THE SAME - The disclosure provides an electrolyte supplement system in an aluminium electrolysis process, which includes low-molecular-ratio cryolite, wherein the low-molecular-ratio cryolite is selected from mKF.AlF | 05-15-2014 |
20140131216 | POTASSIUM CRYOLITE FOR ALUMINUM ELECTROLYSIS INDUSTRY AND PREPARATION METHOD THEREOF - The invention provides a potassium cryolite for aluminum electrolysis industry, which has a molecular formula: mKF.AlF | 05-15-2014 |
20140134090 | PREPARATION PROCESS OF TRANSITION METAL BORIDE AND USES THEREOF - The invention provides a preparation process of transition metal boride, comprising the following steps: A) aluminum is put in a reactor, inert gas is fed into the reactor after evacuation, the reactor is heated up to 700 to 800° C. and then added with dry potassium fluoborate or sodium fluoborate, monomer boron and cryolite are generated by rapid stirring and reaction for 4 to 6 hours, and the molten liquid at the upper layer is sucked out and the monomer boron is obtained by means of separation; and B) the obtained monomer boron is added with transition metal for reaction at the temperature from 1800 to 2200° C. in order to generate corresponding transition metal boride. | 05-15-2014 |
20140138254 | SODIUM CRYOLITE FOR ALUMINUM ELECTROLYSIS INDUSTRY AND PREPARATION METHOD THEREOF - The invention provides a sodium cryolite for aluminum electrolysis industry, which has a molecular formula: mNaF.AlF | 05-22-2014 |
20140152462 | REMOTE-SIGNAL DATA ACQUISITION METHOD AND DEVICE - The present invention relates to a data acquiring field and provides a remote-signal data acquiring method and device. In the present invention, the remote-signal data are received according to the user's command or a fixed frequency, the currently received remote-signal data are compared with previously received remote-signal data. If the currently received remote-signal data are different from the previously received remote-signal data, a position-alternation indication signal is generated, and the currently received remote-signal data are acquired according to the position-alternation indication signal, thereby the remote-signal data are acquired only when the remote-signal data generate position-alternation and remains unchanged when the remote-signal data do not generate position-alternation. Therefore, the problems of long processing time and low acquiring effect to the remote-signal data of the known method for acquiring the remote-signal data are solved. | 06-05-2014 |
20140161442 | DATA SENDING OR RECEIVING METHOD, DEVICE, AND APPARATUS USED IN OPTICAL FIBER TRANSMISSION - The present invention relates to a fiber transmission field and provides a data sending or receiving method, device, and apparatus used in optical fiber transmission. The method includes: detecting data to be transmitted; encoding one bit pulse width to M parts if the to-be-transmitted data is 0, wherein the first part is a high-level, the later M−1 part is a low-level; encoding one bit pulse width to N parts if the to-be-transmitted data is 1, wherein the first part is a high level, and the later N−1 part is a low-level, the M is not equal to the N but both are integer which is greater than or equal to 2; and sending the encoded level signal. The embodiments of the present invention is for transmitting the binary data to be transmitted by the encoding way to changing the bit width of the data, namely, encoding the binary data 0 and 1 using different number of bits when the bit pulse width of the binary data 0 and 1 are the same, thereby two successive binary data 1 can not appear in the data transmission process, thus avoids signal jitters when the fiber transmits the data with a low speed. | 06-12-2014 |
20140301024 | Electric Base, Electric Gateway, and Electric Gateway Body - An electric base, an electric gateway, and an electric gateway body are provided. The electric base includes: an electric base body, where two guide holes for passing cables in an electric grid are arranged in the electric base body, an output end for outputting a voltage of the cables is arranged on the electric base body and protrudes from the electric base body, and a conductor structure is nested in the electric base body to connect the cables and the output end. The foregoing electric base can output power to enable the electric gateway body to operate, thereby effectively saving the cost of an electric gateway in the prior art, and meanwhile expanding the application scope of an electric gateway. | 10-09-2014 |