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    • 2. 发明申请
    • Print head pressure control architectures
    • 打印头压力控制架构
    • US20050157129A1
    • 2005-07-21
    • US10760593
    • 2004-01-21
    • Eric MerzBrian HiltonKazuyuki OdaTakatoshi Tsuchiya
    • Eric MerzBrian HiltonKazuyuki OdaTakatoshi Tsuchiya
    • B05C5/00B05C11/10B41J2/175
    • B41J2/17513B41J2/17563
    • A fluid container, such as, for example, an inkjet print head cartridge, architecture uses a relatively large filter that is located below a negative pressure material chamber and a free ink chamber in a side-by-side relationship. The negative pressure material volume relative to a free ink chamber value can me made to be approximately one to one. Both chambers overlie an ink manifold/delivery port and are separated from the delivery port by a filter. Flow impedance of the cartridge is reduced, as a result, in any orientation of the cartridge. The filter may be separated from, or in contact with a negative pressure material. A cartridge lid is provided with a negative pressure material chamber which is suspended into the cartridge. A negative pressure material having a fiber felt construction is provided.
    • 流体容器,例如喷墨打印头盒,结构使用位于负压材料室下方的相对较大的过滤器和并排关系的自由油墨室。 相对于自由墨水室值的负压材料体积可以使其大致为一比一。 两个腔室都覆盖在墨水歧管/输送口上,并通过过滤器与输送口分开。 因此,盒的流动阻抗减小,因此在盒的任何取向上。 过滤器可以与负压材料分离或与负压材料接触。 盒盖设有负压材料室,其被悬挂在盒中。 提供具有纤维毡结构的负压材料。
    • 4. 发明申请
    • Systems and methods for vent path leakage prevention
    • 排气通道泄漏防护系统和方法
    • US20050110848A1
    • 2005-05-26
    • US10721353
    • 2003-11-26
    • Takatoshi TsuchiyaEric MerzKazuyuki OdaBrian Hilton
    • Takatoshi TsuchiyaEric MerzKazuyuki OdaBrian Hilton
    • B41J2/175
    • B41J2/17523B41J2/17513B41J2/17553
    • A fluid ejection container system provides a first container that contains the fluid, the first container being evacuated to negative gauge pressure when being filled with the fluid, a second container having a capillary medium that contains the fluid, a passage between the first and second containers communicating the fluid at a level wherein the passage is wetted with the fluid, a ventilation port to communicate air between an interior region in the fluid ejection system and ambient, at least one spill over region to communicate the fluid with the second container, and a plurality of channels to communicate at least the air between the interior region and the second container; wherein the at least one spill over region has sufficient volume to contain a quantity of the fluid that migrates out of the second container. The fluid ejection container system also provides a lid for sealing the first and second containers from the ambient, wherein the channels are disposed on the lid.
    • 流体喷射容器系统提供容纳流体的第一容器,当填充流体时第一容器被抽空至负表压;具有容纳流体的毛细管介质的第二容器,第一和第二容器之间的通道 在流体与流体接触的水平面上传送流体;通气口,用于在流体喷射系统的内部区域和环境之间连通空气,至少一个溢出区域以使流体与第二容器连通;以及 多个通道以至少使内部区域和第二容器之间的空气连通; 其中所述至少一个溢出区域具有足够的体积以容纳从第二容器迁出的一定量的流体。 流体喷射容器系统还提供用于将第一和第二容器与环境密封的盖,其中通道设置在盖上。
    • 5. 发明申请
    • Method for attaching a fluid container to a fluid ejector in a fluid ejection device
    • 将流体容器附接到流体喷射装置中的流体喷射器的方法
    • US20050168508A1
    • 2005-08-04
    • US10766008
    • 2004-01-29
    • Brian HiltonEric MerzTakatoshi TsuchiyaHiroki Murakami
    • Brian HiltonEric MerzTakatoshi TsuchiyaHiroki Murakami
    • B41J2/16B41J2/175B41J29/38
    • B41J2/17513B41J2/17509Y10T156/1043
    • A method for joining fluid containers and fluid ejectors in a fluid ejecting device are provided. The fluid container includes one or more heat stakes and a substrate includes one or more apertures for receiving the heat stakes and one or more three-dimensional features in the vicinity of the one or more apertures. The fluid ejector and optionally an elastic member are interposed between the fluid container and the substrate. Thermal energy is applied to the one or more heat stakes so that the one or more heat stakes soften to occupy the apertures and three-dimensional features of the substrate and pressure is applied to maintain contact between the fluid container, elastic member, fluid ejector and substrate. The present invention is also directed to substrate including one or more apertures for receiving heat stakes and one or more three-dimensional features in the vicinity of the one or more apertures.
    • 提供了一种在流体喷射装置中连接流体容器和流体喷射器的方法。 流体容器包括一个或多个热桩,并且衬底包括用于接收热桩的一个或多个孔和一个或多个孔附近的一个或多个三维特征。 流体喷射器和可选地弹性构件插入在流体容器和基底之间。 将热能施加到一个或多个热桩上,使得一个或多个热桩软化以占据孔,并且施加衬底的三维特征并施加压力以保持流体容器,弹性构件,流体喷射器和 基质。 本发明还涉及包括用于接收热桩的一个或多个孔和一个或多个孔附近的一个或多个三维特征的衬底。
    • 6. 发明申请
    • Printer with printhead fully traveling around drive belt loop
    • 带打印头的打印机完全绕传动带环路传播
    • US20050151768A1
    • 2005-07-14
    • US10752721
    • 2004-01-08
    • Eric MerzBrian Hilton
    • Eric MerzBrian Hilton
    • B41J2/01B41J19/00B41J19/20B41J29/38
    • B41J19/005
    • A drive assembly for a printer includes an endless loop drive path and guide structure that allows a printhead to operate in either reciprocal or endless loop modes in which the printed traverse both a liner and an arcuate portion of the drive path. This provides a printer architecture in which a printhead may be endlessly driven at a constant speed in one direction to provide multiple print swaths separated spatially. This eliminates the need for decleration/acceleration changes required in reciprocal printer architectures and is capable of increased throughput by defining arcuate turnaround zones that can be traversed by the printhead faster than the time it takes to slow, stop and reverse a conentional reciprocal printhead assembly. This robust printer architecture also allows flexibliity in use of multiple printheads with simultaneous printing, simultanouse both side printing, and duplex capabilities.
    • 用于打印机的驱动组件包括环形环驱动路径和导向结构,其允许打印头以往复或无限循环模式操作,其中打印的横移既是驱动路径的衬套和弓形部分。 这提供了一种打印机结构,其中打印头可以在一个方向上以恒定速度无休止地驱动,以提供在空间上分离的多个打印条带。 这消除了在往复式打印机架构中所需的解除/加速变化的需要,并且通过限定弓形转向区域可以提高吞吐量,该区域可以比打印速度慢,停止和反转一个相互往复的打印头组件所需的时间快得多。 这种坚固的打印机架构还允许灵活性地使用多个打印头,同时打印,同时打印和双面打印功能。
    • 8. 发明申请
    • Systems and methods for controllably refilling a fluid quantity sensing fluid ejection head
    • 用于可控地重新填充流体量感测流体喷射头的系统和方法
    • US20050110815A1
    • 2005-05-26
    • US10721275
    • 2003-11-26
    • Eric MerzBrian Hilton
    • Eric MerzBrian Hilton
    • B41J2/175B41J2/195
    • B41J2/17566B41J2/17509
    • A controller for a fluid ejecting system having a refillable container includes an ejection count initializing circuit, routine or application, a count incrementing circuit, routine or application, at least one fluid level indicator, and a fluid quantity circuit, routine or application for determining an expended quantity of fluid, a fluid reserve capacity circuit, routine or application for determining a fluid reserve capacity in the container, an ejection job determining circuit, routine or application for determining a fluid job requirement, a reserve comparing circuit, routine or application to compare the fluid reserve capacity and the fluid job requirement, and a refill condition determining circuit, routine or application to determine that the container is to be refilled. Counts for a ejection amount and a reserve capacity are incremented in response to a specific amount of fluid being ejected from the container. The expended quantity of fluid is based on the ejection amount count subsequent to the fluid level being indicated. The fluid reserve capacity is based on the reserve capacity count and the expended quantity of fluid. The fluid job requirement is based on the expended quantity of fluid and a job number of ejected amounts of fluid. The container is determined to be refilled upon at least a condition wherein the fluid job requirement exceeds the fluid reserve capacity, and a condition wherein the fluid level is below a refill threshold.
    • 用于具有可再填充容器的流体喷射系统的控制器包括喷射计数初始化电路,程序或应用,计数递增电路,程序或应用,至少一个液位指示器和流体量电路,用于确定 流体储备容量回路,用于确定容器中流体储备容量的程序或应用程序,排出作业确定电路,用于确定流体工作要求的程序或应用程序,备用比较电路,比较例程或应用程序 流体储备容量和流体工作要求,以及重新填充条件确定电路,程序或应用程序以确定容器将被重新填充。 响应于从容器喷出的特定量的流体,喷射量和储备容量的计数增加。 流体的消耗量基于指示流体液面之后的喷射量计数。 流体储备能力基于储量和计量流量。 流体工作要求是基于流体的消耗量和排出量的流体的工作数量。 确定容器至少在其中流体作业要求超过流体储备容量的条件下重新填充,以及其中液面低于再填充阈值的条件。