子分类:
| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 1 | 图像形成装置 | CN201110053333.7 | 2011-03-04 | CN102193369A | 2011-09-21 | 高田一正 |
| 一种图像形成装置,所述图像形成装置在单色图像形成时,集成电路中的彩色图像形成用的图像处理电路、彩色图像形成用的激光控制电路以及彩色图像形成用的数据处理电路停止。该图像形成装置包括:多个图像载体;曝光单元,所述曝光单元包括发出激光束的多个激光单元,并通过从所述各激光单元发出的激光束对所述各图像载体进行主扫描及副扫描;激光检测单元,将从所述各激光单元之中的特定的一个激光单元发出的激光束检测为所述主扫描的基准位置;集成电路,包括多个图像处理电路、多个激光控制电路、多个数据处理电路、选择部、多个第一门电路、多个第二门电路和选择电路;以及控制部。 | ||||||
| 2 | 静电印刷装置以及静电印刷方法 | CN02813205.X | 2002-06-24 | CN1522202A | 2004-08-18 | 安藤今朝男 |
| 本发明的静电印刷装置,将粉体油墨涂抹到形成有预定的印刷图案的丝网上,并通过在该丝网与被印刷物之间施加电压,使上述粉体油墨附着在上述被印刷物上。在上述被印刷物(1)的上方移动自如地设置了多个丝网(34a~34d)。以轴(46)为中心旋转自如地设置多个丝网(34a~34d),通过使丝网(34a~34d)以上述轴(46)为中心旋转,使该丝网(34a~34d)移动到上述被印刷物(1)的上方。 | ||||||
| 3 | 能量有效RF振荡器 | CN99803173.9 | 1999-12-20 | CN1291139A | 2001-04-11 | 丹尼斯·波卢特诺 |
| 用于操作标准电子束印刷卡盘(如18英寸600DPI印刷卡盘)的电子束印刷机组件包括具有铁粉铁芯变压器的RF发生器,和与变压器操作连接的双脉冲宽度发生器。RF发生器也包括电源驱动器,控制逻辑,和振荡器反馈电路。双脉冲宽度发生器可以包括一个与非门,一个电容,两个电阻,和一个二极管,所有的都连接到可调电压源。变压器铁芯可以是螺旋管形,和一氧化碳SF铁芯。使用这个RF发生器能够使以大于200FPM速度移动的基板成象,能够以有效的方式以大约5MHz的频率操作,以消除由于激励过度的变压器引起的印刷梯度,消除由于铁芯损耗引起的变压器温度异常,以在变压器结构和设计中提供更大的灵活性,和在变压器驱动晶体管中更小的电源消耗。 | ||||||
| 4 | 静电印刷装置 | CN02813205.X | 2002-06-24 | CN1294008C | 2007-01-10 | 安藤朝男 |
| 本发明的静电印刷装置,将粉体油墨涂抹到形成有预定的印刷图案的丝网上,并通过在该丝网与被印刷物之间施加电压,使上述粉体油墨附着在上述被印刷物上。在上述被印刷物(1)的上方移动自如地设置了多个丝网(34a~34d)。以轴(46)为中心旋转自如地设置多个丝网(34a~34d),通过使丝网(34a~34d)以上述轴(46)为中心旋转,使该丝网(34a~34d)移动到上述被印刷物(1)的上方。 | ||||||
| 5 | 顺应性的微型器件转移头部 | CN201380027965.3 | 2013-05-01 | CN104335339A | 2015-02-04 | A·比布尔; J·A·希金森; 胡馨华 |
| 本发明公开了顺应性的微型器件转移头部和头部阵列。在一个实施例中,微型器件转移头部包括弹簧部分,该弹簧部分可挠曲到位于基部衬底和弹簧部分之间的空间中。 | ||||||
| 6 | 曝光装置以及图像形成装置 | CN201010268130.5 | 2010-08-25 | CN102004409B | 2014-02-26 | 增田宪介 |
| 本发明涉及一种能够抑制随环境变动而发生的图像形成劣化并力图减少元件数量以降低成本的曝光装置、以及搭载该曝光装置的图像形成装置。其构成为包括:发光元件阵列(101);光源保持部件(102),用于保持发光元件阵列;成像元件阵列(103),将发光元件阵列发射的光束会聚到感光体(10)上;光学元件保持部件(104),在光源保持部件上保持成像元件阵列,使成像元件阵列与发光元件阵列之间保持预定间距;定位部件(105),在感光体上支持光源保持部件,使光源保持部件上的发光元件阵列与感光体之间保持预定距离,从发光元件阵列的发光点位置观察时,定位部件中用于支持光源保持部件的位置即螺丝(106)位于感光体的相反侧。 | ||||||
| 7 | 曝光装置以及图像形成装置 | CN201010268130.5 | 2010-08-25 | CN102004409A | 2011-04-06 | 增田宪介 |
| 本发明涉及一种能够抑制随环境变动而发生的图像形成劣化并力图减少元件数量以降低成本的曝光装置、以及搭载该曝光装置的图像形成装置。其构成为包括:发光元件阵列(101);光源保持部件(102),用于保持发光元件阵列;成像元件阵列(103),将发光元件阵列发射的光束会聚到感光体(10)上;光学元件保持部件(104),在光源保持部件上保持成像元件阵列,使成像元件阵列与发光元件阵列之间保持预定间距;定位部件(105),在感光体上支持光源保持部件,使光源保持部件上的发光元件阵列与感光体之间保持预定距离,从发光元件阵列的发光点位置观察时,定位部件中用于支持光源保持部件的位置即螺丝(106)位于感光体的相反侧。 | ||||||
| 8 | COMPLIANT MICRO DEVICE TRANSFER HEAD | EP13788027.4 | 2013-05-01 | EP2847789B1 | 2017-12-27 | BIBL, Andreas; HIGGINSON, John A.; HU, Hsin-Hua |
| A compliant micro device transfer head and head array are disclosed. In an embodiment a micro device transfer head includes a spring portion that is deflectable into a space between a base substrate and the spring portion. | ||||||
| 9 | ENERGY EFFICIENT RF OSCILLATOR | EP99964294.5 | 1999-12-20 | EP1056599A1 | 2000-12-06 | POLLUTRO, Dennis |
| An electron beam printer assembly for operating a standard electron beam print cartridge (such as an eighteen inch 600 DPI print cartridge) includes an RF generator which has a powdered iron core transformer, and a dual pulse width generator operatively connected to the transformer. The RF generator also includes a power driver, control logic, and an oscillator feedback circuit. The dual pulse width generator may comprise a NOR gate, a capacitor, two resistors, and a diode, all connected to an adjustable voltage source. The transformer core may be toroid-shaped, and of carbonyl SF. Using this RF generator it is possible to image a substrate moving at a speed of greater than 200 FPM, and to operate at a frequency of about 5 MHz in an efficient manner, to eliminate print gradients due to an overdriven transformer, to eliminate transformer temperature failures due to core loss, and to provide greater flexibility in transformer construction and design, and less power loss in the transformer drive transistor. | ||||||
| 10 | Image forming method and image forming apparatus | EP90303919.6 | 1990-04-11 | EP0392826A2 | 1990-10-17 | Yuasa, Toshiya; Kobayashi, Motokazu; Arahara, Kozo; Fukumoto, Hiroshi; Matsumoto, Kenichi; Tohyama, Noboru; Kai, Takashi |
There is provided a method and apparatus for forming an image (8) which includes providing a recording composition capable of changing its adhesivity corresponding to the polarity of a voltage applied thereto between a pair of electrodes. The recording composition has a transfer characteristic having a tendency to change by loss of at least one component of the recording composition. A voltage is applied between the pair of electrodes to attach the recording composition to one of the pair of electrodes. Any such change in the transfer characteristic of the recording composition is detected during the process. In response to any change in the transfer characteristic additional component is added to the recording composition to compensate for that change. |
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| 11 | Preheating apparatus for an electrolytic printer | EP82100842.2 | 1982-02-05 | EP0059336A2 | 1982-09-08 | Pawletko, Joseph Paul |
A preheating pad (36) and assembly for electrolytic printing apparatus (8) is provided. The pad (36) is adjustably mounted to a write head (18) of the printer (8) for movement normal to the recording medium (10) used therein. The pad (36) is fabricated from a ceramic chip and includes a resistive heating element that is protected by a thin bottom layer provided. The pad (36) is joined to an insulated carrier arm (40) by a spring (38) which serves to electrically and mechanically couple the pad (36) and the print head (38). The biasing effect made possible by the spring (38) allows the pad contact pressure with the recording medium surface to be tuned or adjusted as required. In operation, the pad's position is adjusted to force moisture deposited by an applicator (30,32) on the surface of the recording medium (10) to penetrate the recording medium's surface layer while simultaneously heating both the surface layer's constituent materials and the fluid being driven therein. |
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| 12 | Head unit | US15714024 | 2017-09-25 | US10040286B2 | 2018-08-07 | Toshihito Takagi |
| Disclosed a head unit including: a plurality of ejecting units that eject liquids; a driving IC that drives the plurality of ejecting units; a substrate; a first electrode group that includes a plurality of electrodes connected to the driving IC and the substrate; and a second electrode group that includes a plurality of electrodes connected to the driving IC and the substrate, in which the driving IC is a rectangular shape in plan view. | ||||||
| 13 | Compliant micro device transfer head | US15279083 | 2016-09-28 | US09895902B2 | 2018-02-20 | Andreas Bibl; John A. Higginson; Hsin-Hua Hu |
| A compliant micro device transfer head and head array are disclosed. In an embodiment a micro device transfer head includes a spring portion that is deflectable into a space between a base substrate and the spring portion. | ||||||
| 14 | System, Method, and Apparatus for Waveform Transformation | US15193879 | 2016-06-27 | US20170005681A1 | 2017-01-05 | Pierre Hervé Nicolas |
| A process for producing biotech adapters includes ionization of inks that are later used to print on any of a multitude of surfaces while under the influence of specialized electromagnetic radiation, thereby such printing creates the missing frequency that will complete the man-made frequency thus obtaining a bio compatible frequency known to be beneficial to the health of the user. For example, the process is used to print a biotech adapter having an adhesive backing. The biotech adapter is then attached (e.g. by the adhesive) to the user's electronic device (e.g., cellular phone), preferably at a location where such harmful radio waves are emitted in the direction of the user's head. The biotech adapter reacts to the harmful radio waves, completing the missing radio waves by emitting radio waves that are known to be beneficial to humans. | ||||||
| 15 | Image forming method, image forming apparatus, and print material production method to form an electrostatic latent image by selective light power exposure | US14705423 | 2015-05-06 | US09517636B2 | 2016-12-13 | Hiroyuki Suhara; Masato Iio; Hiroto Tachibana |
| An image forming method forms an electrostatic latent image corresponding to an image pattern including an image portion and a non-image portion by exposing a surface of an image bearer with light according to the image pattern. The image portion includes a plurality of pixels. Among the pixels constituting the image portion, at least a group of pixels existing at a boundary with respect to the non-image portion is set as a non-exposure pixel group. Among the pixels constituting the image portion, at least a group of pixels existing at a boundary with respect to the non-exposure pixel group is set as a high power exposure pixel group where exposure is performed with light of a higher light power value than a predetermined light power value required for exposing the image portion. | ||||||
| 16 | Image forming apparatus, image forming method, and recording medium storing an image forming program | US14721101 | 2015-05-26 | US09482985B2 | 2016-11-01 | Yuusuke Kohri; Masayuki Hayashi; Motohiro Kawanabe; Yoshinori Shirasaki; Masatoshi Murakami; Akinori Yamaguchi |
| An image forming apparatus includes multiple exposure units each including multiple light emitting elements, a reading unit that reads data to be used for exposure by each one of the exposure units, one at a time from the exposure unit by the time the exposure units starts exposure, a storing unit that stores the data read by the reading unit, and a transfer unit that transfers the data stored in the storing unit to the exposure unit by the time the exposure unit starts exposure. | ||||||
| 17 | OPTICAL SCANNING DEVICE AND IMAGE FORMING APPARATUS | US15046468 | 2016-02-18 | US20160161906A1 | 2016-06-09 | Kazunori WATANABE; Yoshinobu SAKAUE; Susumu NARITA; Hiroshi JOHNO |
| An optical scanning device includes a light source configured to emit a light beam; a rotary deflector configured to perform optical scanning by reflecting and deflecting the light beam emitted from the light source while rotating; an optical system forming member configured to form a path of the light beam; and a resonator having a resonance frequency corresponding to a sound generated by rotational drive of the rotary deflector. The rotary deflector is installed in a closed space. The resonator is installed so that the sound within the closed space is absorbed. | ||||||
| 18 | OPTICAL SCANNING DEVICE AND IMAGE FORMING APPARATUS | US14720022 | 2015-05-22 | US20150338761A1 | 2015-11-26 | Kazunori WATANABE; Yoshinobu SAKAUE; Susumu NARITA; Hiroshi JOHNO |
| An optical scanning device includes a light source configured to emit a light beam; a rotary deflector configured to perform optical scanning by reflecting and deflecting the light beam emitted from the light source while rotating; an optical system forming member configured to form a path of the light beam; and a resonator having a resonance frequency corresponding to a sound generated by rotational drive of the rotary deflector. The rotary deflector is installed in a closed space. The resonator is installed so that the sound within the closed space is absorbed. | ||||||
| 19 | Rewritable recording medium, image recording set, and image recording method | US13431177 | 2012-03-27 | US08810896B2 | 2014-08-19 | Nozomu Tamoto |
| A rewritable recording medium including: a base material; and an image recording layer enclosed by the base material, wherein the image recording layer contains: electrophoretic particles, magnetophoretic particles, or both of the electrophoretic particles and the magnetophoretic particles; a dispersion medium; and a thermoreversible gelling agent, and wherein the dispersion medium is in contact with the base material, and wherein image recording and image erasing can be repeatedly performed on the rewritable recording medium by an external image recording device. | ||||||
| 20 | Light emitting element array chip, light emitting element head, and image forming apparatus | US13556523 | 2012-07-24 | US08780148B2 | 2014-07-15 | Seiji Ohno |
| A light emitting element array chip includes first and second light emitting element rows including light emitting elements that are arranged in a main scanning direction in a zigzag, a first light emission signal line transmitting a light emission signal for allowing the light emitting elements forming the first light emitting element row to emit light, and a second light emission signal line transmitting a light emission signal for allowing the light emitting elements forming the second light emitting element row to emit light, wherein the first light emission signal line or the second light emission signal line is arranged in the main scanning direction between the first light emitting element row and the second light emitting element row and is provided in regions between the light emitting elements forming the first light emitting element row and between the light emitting elements forming the second light emitting element row. | ||||||
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