| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 361 | Ink jet recorder | JP175795 | 1995-01-10 | JPH08187842A | 1996-07-23 | KAWAGUCHI TAKAO; ISHIKAWA TETSUO; TAKIZAWA YOSHIHARU; NAKAGAKI MITSUHIRO |
| PURPOSE: To provide an ink jet recorder capable of obtaining stable printing quality by stabilizing a flight orbit of an ink particle. CONSTITUTION: A means wherein ink is made a particle with a nozzle 1, an electrostrictive element 2, and an exciting power source 3, a means wherein a charge is added to the ink particle by a charged electrode 4, and a means wherein the charged ink particle 6 is controlled by deflection by a deflected electric field 7 made by a deflecting electrode 5 are provided. The ink particle 6 is flown in a specific orbit to reach a specific position, a printed dot 13 is formed on a material to be printed 12, and printing is carried out. Then, a means for removing an electricity charged on the material to be printed 12 or the like by blowing an ion having a positive of negative charge made by an ionization means composed of a corona discharger 18 and a high-tension power source 19 on the material to be printed 12 or its surrounding components from an ion blowing means composed of a blast means 17, a duct line 16, and an air nozzle 14, is provided. | ||||||
| 362 | Ink jet recorder | JP11649378 | 1978-09-25 | JPS5542834A | 1980-03-26 | JINNAI KOUICHIROU; IWASAKI KIYUUHACHIROU |
| PURPOSE: To obtain the title recorder on which precise positioning of girder is not required and easy in maintaining deflection accuracy by installing girder at a specified position between the deflection means and the recording sheet, and providing the secondary deflection means to eliminate the deflection value. CONSTITUTION: On the horizontal deflection terminal 14 and the vertical deflection terminal 15 of the primary deflection means, D.C. current voltage V x and V y are applied respectively, while on the vertical terminal 16, D.C. voltage V -y which is of the same potential as V y but of the opposite flow direction is applied. Among the ink drops jetted out from the ink head 11, those charged ink drops being charged at the charging terminal 12 are deflected to the direction of upward aslantwise when thet pass the first deflection means, and are deflected to the direction of downward when they pass the second deflection means, flying along the path as shown by the dotted line a, and are attached on the recording surface of the recording sheet A. Unnecessary ink drops which are not charged fly direct along the dotted line b, accordingly, the girder 19 is required to be positioned on the vertical level only sufficient enough to catch those unnecessary ink drops flying along the straight line. COPYRIGHT: (C)1980,JPO&Japio | ||||||
| 363 | Inkjet recorder | JP2009048046 | 2009-03-02 | JP2010201699A | 2010-09-16 | SANO YUICHIRO; INOUE TOMOHIRO; SANO KIYOSHI; FUJIKURA SEIJI; DOI AKIRA; KANAMARU MASATOSHI |
| <P>PROBLEM TO BE SOLVED: To provide a multinozzle continuous discharge type inkjet recorder of high reliability capable of enhancing a charge efficiency of a liquid droplet and capable of regulating visually a charge electrode position. <P>SOLUTION: This multinozzle continuous discharge type inkjet recorder includes a multinozzle having a plurality of nozzles adjacent-arranged line-likely, and for discharging and forming the liquid droplet from each nozzle, a plurality of charge electrodes installed in the vicinity of a flying route of the liquid droplet delivered from each nozzle, and for charging the each droplet to an optional charge amount, and a deflection electrode arranged in one part of the flying route of the liquid droplet, and for forming a deflection electric field for deflecting the charged flying droplet by impressing a high voltage, the inkjet recorder is provided with an auxiliary charge electrode arranged opposedly corresponding to each charge electrode, with the flying route of the liquid droplet delivered from the nozzle therebetween, the auxiliary charge electrode is formed integrally on a plate-like transparent insulating substrate, and further an electric field shielding member is installed between the charge electrode and the deflection electrode, to shield the electric field generated by impressing the high voltage to the deflection electrode. <P>COPYRIGHT: (C)2010,JPO&INPIT | ||||||
| 364 | Inkjet recorder | JP17969183 | 1983-09-27 | JPS6071261A | 1985-04-23 | KIMURA MASATOSHI; SATOU KAZUHIKO; NAKAJIMA JIYUNZOU |
| PURPOSE:To lower the cost of a recorder by a method wherein a charged electrode and an ink drop attaching body are built on the surface of the same insulation substrate and an introduced current generated with the flying and attachment of charged ink drops is detected to determine whether injection is done at a high accuracy. CONSTITUTION:A voltage pulse is applied to a piezo-eletric element 12 of a head 10 to be converted into a pressure pulse which is transmitted to a nozzle 11 and an ink is extruded from the nozzle 11 to fly in drops 13. At this point, several ten - several hundred V is applied between the nozzle 11 and an electrode 14 of an electrode plate 18 in which an ink drop attaching body 15 is connected to a detection circuit 16 and additionally, the charged electrode 14 and the body 15 are built on the same insulation substrate 17 to have ink in charged ink drops flying and as it approaches the body 15, an electric charge is induced in the body 15 opposite in the polarity to the charge of the ink drops 13 and amplified to the positive voltage about 100 times with the circuit 16 to be compared with the reference voltage by a comparator therein 16, which outputs a detection signal when it exceeds the reference voltage. Thus, the injection of ink drops, namely, possible nozzle clogging can be detected. | ||||||
| 365 | Magnetic fluid recording system | JP13090680 | 1980-09-19 | JPS5756278A | 1982-04-03 | NAGATOMI KAZUYASU; DAITOU CHIAKI |
| PURPOSE: To obtain high quality record whose recording depth is deep by a magnetic fluid recorder wherein when recording is carried out by it, in addition to recording signals auxiliary signals are energized earlier than the energizing of the recording signals to quicken the start of flying of magnetic ink. CONSTITUTION: Recording signals are sent to a control electrode G by a picture signal controlling circuit 12 and a control electrode driver 13 synchronously with main scanning signals (j) and sub scanning synchronous signals (k) generated by a base clock generating circuit 11. A stylus scanning circuit 14 successively generates stylus scanning signals lWr synchronously with synchronous signals k, j. A t 2 period before the signal j, auxiliary pulse signals aWy are generated by an auxiliary pulse generating circuit 17, and OR gates 15 output logical sums of the auxiliary pulse signals sWy and the scanning signals lWr as stylus driving signals 1W7 to a stylus driver 16. The inks bulged on the stylus electrodes S are made ready to fly by the auxiliary pulse signals, and start to fly at the same time with the scanning signals. COPYRIGHT: (C)1982,JPO&Japio | ||||||
| 366 | Heat-fusible type ink jet recorder | JP19985183 | 1983-10-25 | JPS6090775A | 1985-05-21 | HONMA JIYUNICHI |
| PURPOSE:To reduce the period of time required for heating at the time of starting, enable to simplify construction and to reduce size, simplify the construction of an ink-supplying part and obtain the titled recorder excellent in maintainability and operability, by jetting a heat-fusible ink while selectively controlling by an electrostatic attractive force. CONSTITUTION:The recorder comprises an ink-supplying part 2 for appropriately supplying a granular or lump form heat-fusible ink 1, a heating container part 3 having a holed construction for receiving the ink 11 supplied from the part 2 and heating the ink 11 to melt the latter, an ink-jetting substrate 6 receiving and reserving the liquid ink 12 supplied from the container part 3 and provided with a plurality of electrodes 4 arranged in a plate form and a heating means 5, a plurality of counter electrodes 8 arranged on the back side of a recording paper 7 and provided with a polarity opposite to that of the electrodes 4, and an ink jet controlling part 9 for selectively impressing voltages on the electrodes 4, 8 in accordance with an image signal to jet the ink as ink droplets 13 by electrostatic attractive forces. The liquefied ink is caused to fly to record an image on the paper 7. | ||||||
| 367 | Dry powder mixes comprising phase change materials | US44819 | 1993-04-08 | US5370814A | 1994-12-06 | Ival O. Salyer |
| A free flowing, conformable powder-like mix of silica particles and a phase change material (PCM) is provided. The silica particles have a critical size of about 0.005 to about 0.025 microns and the PCM must be added to the silica in an amount of 75% or less PCM per combined weight of silica and PCM. The powder-like mix can be used in tableware items, medical wraps, tree wraps, garments, quilts and blankets, and particularly in applications for heat protection for heat sensitive items, such as aircraft flight recorders, and for preventing brake fade in automobiles, buses, trucks and aircraft. | ||||||
| 368 | Heat shielded memory unit for an aircraft flight data recorder | US687910 | 1984-12-31 | US4694119A | 1987-09-15 | Johannes B. Groenewegen |
| Solid state memory devices employed in crash survivable flight data recorders must be thermally insulated to prevent loss of stored data if the aircraft burns. To provide adequate thermal isolation at minimal size, the solid state electronic memory devices (26) are encapsulated in a synthetic organic wax or pentaerythritol (28) that exhibits a phase transition at a temperature: (a) above the normal operating temperature of the memory unit (10); and below the maximum acceptable peak temperature for the memory devices (26). The synthetic organic wax of pentaerythritol (28) is surrounded by a thermal liner (18) constructed of solid thermal insulating material. A metal enclosure (12) houses and protects the thermal liner (18), the synthetic organic was or pentaerythritol (28) and the memory devices (26). | ||||||
| 369 | Dry powder mixes comprising phase change materials | US315256 | 1994-09-29 | US5477917A | 1995-12-26 | Ival O. Salyer |
| A free flowing, conformable powder-like mix of silica particles and a phase change material (PCM) is provided. The silica particles have a critical size of about 0.005 to about 0.025 microns and the PCM must be added to the silica in an amount of 75% or less PCM per combined weight of silica and PCM. The powder-like mix can be used in tableware items, medical wraps, tree wraps, garments, quilts and blankets, and particularly in applications for heat protection for heat sensitive items, such as aircraft flight recorders, and for preventing brake fade in automobiles, buses, trucks and aircraft. | ||||||
| 370 | Bidirectional magnetic read/write recording head surface contour with plurality of Bernoulli Pocket cavities for generating very low media-to-head separations | US988196 | 1997-12-10 | US5969912A | 1999-10-19 | James Robert Cope |
| A bi-directional magnetic recording/reproduce head surface contour that provides the lowest possible Head-to-Media separation at high media-to-head relative speeds with accompanying best condition head or media wear conditions. The Bernoulli Pockets provide the mechanism that forces the media to fly very close to the recording head gap(s). Depending upon the speed, data rate and capacity goals of the Tape Product the Bernoulli Pocket design can be developed per this invention to provide the required flying conditions. This operating performance is equivalent in both directions selected by a Magnetic Data Recorder. It is intended for use on single, or multiple gap data recorders that record data upon media in a Serpentine manner, in single track or multiple track formats, but may be used in single direction Data Recorders also. The design is not limited to a particular width of tape and can be used on many different data recorders using various width media. It will work well at low, medium or high speeds, but it's main advantage is reliable operation at high speeds (above 3 Meters/Sec or 120 Inches/Second). | ||||||
| 371 | Ink flying recorder | JP9838980 | 1980-07-17 | JPS5724269A | 1982-02-08 | MARUNO SUSUMU; NAKAGAWA MASAKI |
| PURPOSE:To prevent the sedimentation phenomenon of a magnetic fluid toner, to smooth the supply of the magnetic fluid toner to the nose of a recording electrode and to eliminate the turbulence of the shape of a projection by separating a magnet for the projection from the recording electrode in the magnetic ink flying recorder. CONSTITUTION:The recording electrode 1 is magnetized as seen in the figures by magnetic flux emitted from the magnets 2a, 2b for the projection, and the projection 6 is formed near the recording electrode 1 of the liquid surface of the magnetic fluid toner 3. When high voltage is applied between the recording electrode and a controlling electrode through a voltage applying means 9, coulomb force functions to the nose of the projection 6, the magnetic fluid toner flies toward a recorder, and printing is conducted. When the magnets for the projection are not contacted directly with the magnetic fluid toner in this manner, a sedimentation layer of the magnetic powder of the magnetic fluid toner is not generated, and leakage flux on the magnets for the projection is not shielded, thus resulting is no turbulence of the shape of the projection, then ensuring stable printing having high quality. | ||||||
| 372 | Ink jet type recorder | JP7137383 | 1983-04-25 | JPS59198158A | 1984-11-09 | FUJIMORI YOSHINORI; OOWA TAKESHI |
| PURPOSE:To obtain the titled recorder, whose ink head is strong for contamination from ink, easily recovering unnecessary ink droplets, by hardening or evaporating unnecessary ink droplets during flying by the irradiation of radiation energy. CONSTITUTION:Color ink an others hardening by the reaction of light are used for ink, continuously injected from print head 20 and flown to record chart 11. The signal for ejecting unnecessary ink drops 19 is supplied to lighting circuit 34 via selective circuit 32 and signal conversion circuit 33 by pattern information with key board or the like, and a light source 31 is lighted. The light from light source 31 is converged with reflector 31a and lens 31b and projected to ink droplet. Accordingly, the droplet 19 is hardened and made not to adhere to record chart 11. | ||||||
| 373 | Liquid jet recorder | JP22115582 | 1982-12-17 | JPS59111858A | 1984-06-28 | HARA TOSHITAMI; YANO YASUHIRO |
| PURPOSE:To record high-quality pictures with high resolution at high speeds by a method in which the ratio of the distance between the adjacent thermal action faces to the shortest distance between the center of the thermal action faces and the center of the corresponding jet port is set up within a specific value range. CONSTITUTION:In a liquid jet recorder using a heat energy, dimensions and shape are determined such that the relations between the distance PH between the centers of the thermal action faces 107 of the adjacent electricity-heat converters 102 and the shortest distance DOH connecting the center of the thermal action faces 107 with the center of the corresponding orifice 105 meet the equation. In a liquid jet recorder designed in this way, a liquid is discharged from only the orifice 105 corresponding to the thermal action faces 107 constituting the electricity-heat converter 102 in response to a drive signal and flying liquid droplets are formed. An interference, if any, with the adjacent orifice 105 is negligible, and therefore, liquid droplets of constant sizes can be discharged toward a fixed direction with a fixed speed in response to a recording signals. | ||||||
| 374 | Magnetic ink recorder | JP19585581 | 1981-12-04 | JPS5896572A | 1983-06-08 | YOSHIDA NOBUAKI; NAKAGAWA MASAKI; IRIE HIROYUKI; DAITOU CHIAKI |
| PURPOSE:To raise the ink supplying performce to a needle electrode and obtain images of constant density regardless of the variations in the recording density by providing a groove corresponding to the needle electrode on the acute-angled face of an ink-rising magnet in a magnetic ink recorder. CONSTITUTION:Magnetic ink 4 supplied from an ink trap 6 by means of a supply magnet 5 is supplied to a needle electrode 1 (plural) attached to a base 2 through its sloped portion (acute-angled portion) by means of a rising magnet 3, and the ink is flied toward a counter electrode 7 to record images on a recording paper 8. In relation to the rising magnet 3 of said device, grooves 13 of a width slightly wider than the needle electode 1 are formed on the acute-angled face 11 correspondingly to each of the needle electrodes 1. Thus, the supplying performance of magnetic ink from the rising magnet 3 to the needle electrode 1 is greatly improved by application of the capillary force of the grooves 13 and the magnetic force of the edges of the grooves 13, combined with the magnetic force of the acute-angled face 11, and therefore, good quality images can be obtained regardless of the variations in the recording density. | ||||||
| 375 | Device and method for positional error calibration | JP26371499 | 1999-09-17 | JP2001091295A | 2001-04-06 | FUJISE MORIMASA |
| PROBLEM TO BE SOLVED: To measure, input for instrument calibration, and record, on an aircraft to be flight-tested, a true airspeed necessary for the positional error calibration of a barometric altimeter and an airspeed meter of an aircraft and a wind direction and a wind velocity at an altitude where a flight test is performed. SOLUTION: This positional error calibration device comprises a calculation part for calculating true airspeed, wind direction, and wind velocity from a nose direction from an attitude angle meter, ground speed, and airspeed, a recording meter for recording output values from the calculation part, an attitude indicating device and an attitude holding device for indicating and holding a nose direction with the nose direction and output values from the calculation part, a speed indicating device and a speed holding device for indicating and holding the airspeed with the airspeed and the output values from the calculation part, a barometric altitude indicating device and a barometric altitude holding device for indicating and holding the barometric altitude with the barometric altitude and the output values from the calculation part, and an altitude holding device for holding the altitude with the terrain clearance and the output values from the barometric altitude holding device. | ||||||
| 376 | Device and method for monitoring nuclear electric power generation plant | JP28207589 | 1989-10-31 | JPH02179497A | 1990-07-12 | AANORUDO HIRU FUERO |
| PURPOSE: To display the total integral dose and the thermal history of an approved facility by providing a passive detection means for detecting the total integral dose of radioactive rays that a target piece receives, a means for estimating the thermal history, and a means for housing these. CONSTITUTION: A monitoring equipment 10 is made of a die-cast aluminum box 12 for housing a first dose measurement means for measuring the dose of gamma rays and a second dose measurement means for measuring the dose of beta rays, and the first and second dose measurement means constitutes a passive means for detecting the total integral dose of radioactive rays that the target piece receives. The first dose measurement means consists of a long-term monitoring block 14 and a short-term monutoring block 16, and these components are formed so that they can be fitted to a recessed part 30 of a body part 18 of the box 12. A thermal luminescence dose measurement means consists of a thermal luminescence dose meter and a solid flight recorder for thermal integration consists of a means used as a thermal monitoring integrator. Then, there are a stage for bringing the passive means and an estimation means closer to the target piece and mounting them and a stage for analyzing the passive detection means and the estimation means periodically. COPYRIGHT: (C)1990,JPO | ||||||
| 377 | Mechanical and thermal protection device | JP34788992 | 1992-12-28 | JPH05262299A | 1993-10-12 | Gilbert Christien; Yvon Daoulas; イボン・ダウラ; ジルベール・クリスティエン |
| PURPOSE: To provide a mechanical and thermal protection device, being free from danger of damage by expansion at a low temperature and suitable for protecting a data recorder concerning a flight situation of an aircraft. CONSTITUTION: This mechanical and thermal protection device comprises an internal box 3, 4 in which a protection element is housed, an external box 1, 2 which withstands mechanical impact from surroundings, and a filling material filled between the two boxes. The filling material consists of a solid water- storing material 8, 8' having mechanical strength, containing moisture emitted by the action of heat, and having a number of cavities sufficient for preventing expansion at a low temperature, and a stable heat insulator 7, 7' surrounding the water-storing material. The two filling material layers are separated from each other by a reflection layer 5, 6 reflecting a part of heat flux which has passed through the stable heat insulator. COPYRIGHT: (C)1993,JPO | ||||||
| 378 | Device and method for monitoring nuclear power generation plant | JP25004088 | 1988-10-05 | JPH01121795A | 1989-05-15 | AANORUDO HIRU FUERO; ROORENSU MAACHIN POTOKUNITSUKU; RONARUDO UIRIAMU RIRINGU; KENESU FURANSHISU SHIMUSHII |
| PURPOSE: To monitor an approved facility by providing a passive detection means for detecting the total integrated dose of radioactive ray that a target part piece receives and a means for estimating the thermal history of the target part piece. CONSTITUTION: A monitoring equipment 2 mainly consists of a first dose measuring means for measuring the dose of gamma rays and a second dose measuring means for measuring the dose of beta rays and the first and the second dose measuring means constitute a passive detection means for detecting the integral dose of radioactive rays that a valve 4 that is a target part piece receives. A means for estimating the thermal history of the target part piece of the facility is housed in a holder body 18. The estimating means is a one-piece-type thermal monitoring equipment consisting of a thermal monitoring equipment such as a temperature label that changes to an irreversible black color when a peak temperature is reached and a solid flight recorder, thus indicating the total integral dose and thermal history of the target part piece of an approved facility during the operation, at the time of accident, and at the later period of a normal nuclear power generation plant. COPYRIGHT: (C)1989,JPO | ||||||
| 379 | Ink jet recorder | JP517679 | 1979-01-19 | JPS5597962A | 1980-07-25 | NISHIMURA YUKIO; SAITOU SEIJI; TAKAHASHI MICHIKO; IMATAKI HIROYUKI |
| PURPOSE:To provide a recorder of compact and simple construction and form an image at high speed by a method wherein ink droplets jetted from a rotating ink head are charged and deflected according to image signals. CONSTITUTION:Ink droplets of uniform particle size are jetted from plural ink nozzles 6 formed in a rotary ink head 5 in rotation, by maintaining ink characteristics, recording head characteristics, and head driving conditions within predetermined ranges respectively. Charging electrodes 7 each surrounding the nozzle 6 charge the ink droplets by electrostatic induction according to image signals. The charged ink droplets are deflected by annular deflecting electrodes 8 arranged around the head 5, to drop in an annular ink gutter 9. On the other hand, uncharged ink droplets continue flying straight to reach a recording member 10, forming an image thereon. | ||||||
| 380 | APPARATUS AND SYSTEM FOR SMART SEEDING WITHIN CLOUD FORMATIONS | US14685241 | 2015-04-13 | US20160299254A1 | 2016-10-13 | Lorenzo Martinez Martínez De La Escalera; Jorge Joaquin Canto Ibanez; Diego Martinez Martínez De La Escalera; Hernán Rivera Ramos; Lorenzo Martinez Gomez |
| This invention consists of a unique apparatus and system consisting of devices, materials and methods specially engineered to perform high precision and smart cloud seeding by the dispersion of micro and nanoparticles of sodium chloride and similar chemistry compounds at specific locations with the purpose of rain induction and related applications. A safe and precise unmanned aerial vehicle UAV device instrumented with portable thermometer, hygrometer, barometer, anemometer and 3D visual register will scrutinize these internal cloud climate parameters. By means of these real time measurements and communications, a meteorological ground operating team is enabled to perform the data acquisition and processing from the clouds. This device and system be enabled to select the locations suitable for rain induction and perform on site accurate particulate seeding dispersion from a device mounted on the same UAV within the eligible clouds. Typical applications of this apparatus and system besides rain induction are fog condensation for airports, highways and other environments where visibility impairment may have critical consequences. This invention may also provide a valuable tool to provide solutions to control and mitigate snow, sleet and hail effects. | ||||||
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