公开(公告)号：US20230339058A1

公开(公告)日：2023-10-26

申请号：US18344741

申请日：2023-06-29

Applicant: BUNRI Incorporation

Inventor： Makoto Tashiro

IPC: B23Q11/00 ,  B03C1/12

CPC classification number: B23Q11/0064 ,  B03C1/12

Abstract: A magnet separator includes a separator body, a magnet drum and a driving portion. The magnet drum includes a first shaft, a cylinder provided inside the separator body, rotatably supported in the first shaft, an inner cylinder secured to the first shaft inside the cylinder, a magnet provided in the inner cylinder, and a second shaft rotating together with the cylinder. The separator body includes a pair of side walls. The driving portion includes an output portion provided on the outside the separator body. The second shaft penetrates one of the side walls toward outside of the separator body. The output portion is connected to the second shaft.

公开(公告)号：US20180135215A1

公开(公告)日：2018-05-17

申请号：US15807830

申请日：2017-11-09

Applicant: ADMEDES GMBH

Inventor： Florent Budillon ,  Kevin Lehmann ,  Marc O. Braeuner

IPC: D04C3/30 ,  D04C3/22 ,  D04C3/20 ,  B03C1/26

CPC classification number: D04C3/30 ,  B03C1/12 ,  B03C1/26 ,  D04C3/14 ,  D04C3/20 ,  D04C3/22 ,  D04C3/24

Abstract: The present invention relates to a switch for sorting, deflecting, and supplying ferromagnetic elements. Here, the switch comprises at least two electromagnets, which are embodied curved or circular. The magnets may be installed fixed in the switch, on the one hand, or supported on an axis, on the other hand. The ferromagnetic elements are moved by a conveying element through the switches. Advantageously the switch can also be used to control bobbins in a braiding machine. Here, the bobbin can be transferred to another impeller. This way new options are generated with regard to flexibility of braids. Further, this invention offers a considerable reduction of braiding time in case of complex braids.

公开(公告)号：US09724693B2

公开(公告)日：2017-08-08

申请号：US14669531

申请日：2015-03-26

Applicant: GEN-PROBE INCORPORATED

Inventor： Norbert D. Hagen ,  Byron J. Knight ,  David Opalsky

IPC: B03C1/06 ,  B01L3/00 ,  G01N35/00 ,  B03C1/033 ,  B03C1/28 ,  B65B3/04 ,  B03C1/12 ,  B03C1/14 ,  B01L9/00 ,  B25J11/00 ,  C12N15/10

CPC classification number: B01L3/52 ,  B01L3/561 ,  B01L9/52 ,  B01L2300/0609 ,  B01L2300/12 ,  B03C1/0332 ,  B03C1/12 ,  B03C1/14 ,  B03C1/28 ,  B03C1/286 ,  B03C1/288 ,  B03C2201/18 ,  B03C2201/26 ,  B25J11/00 ,  B65B3/04 ,  C12N15/1013 ,  G01N35/0098 ,  Y10T29/49815

Abstract: Methods, systems, and apparatus are provided for automated isolation of selected analytes, to which magnetically-responsive solid supports are bound, from other components of a sample. An apparatus for performing an automated magnetic separation procedure includes a mechanism for effecting linear movement of a magnet between operative and non-operative positions with respect to a receptacle device. A receptacle holding station within which a receptacle device may be temporarily stored prior to moving the receptacle to the apparatus for performing magnetic separation includes magnets for applying a magnetic field to the receptacle device held therein, thereby drawing at least a portion of the magnetically-responsive solid supports out of suspension before the receptacle device is moved to the magnetic separation station. An automated receptacle transport mechanism moves the receptacle devices between the apparatus for performing magnetic separation and the receptacle holding station.

公开(公告)号：US09517472B2

公开(公告)日：2016-12-13

申请号：US13995270

申请日：2011-07-13

Applicant: Tetsuo Ohashi

Inventor： Tetsuo Ohashi

IPC: B03C1/00 ,  B01L3/00 ,  G01N35/00

CPC classification number: G01N35/0098 ,  B01J2219/00364 ,  B01J2219/00466 ,  B01J2219/00468 ,  B01L3/5025 ,  B01L3/5082 ,  B01L2200/0647 ,  B01L2200/0673 ,  B01L2300/0832 ,  B01L2300/0861 ,  B01L2300/087 ,  B01L2400/043 ,  B03C1/00 ,  B03C1/12 ,  B03C1/288 ,  Y10T29/49826

Abstract: The present invention provides a small and low running-cost device capable of minimizing the generation of contamination sources as much as possible while performing a series of all the desired manipulations. A device for manipulating a target component in a manipulation tube, comprising: a manipulation tube comprising a tube having an optionally-closeable open end for supplying a sample containing a target component at one end and a closed end at the other end, and a manipulation medium accommodated in the tube and having a gel layer and an aqueous liquid layer multilayered in a longitudinal direction of the tube; magnetic particles that should transport the target component; and magnetic field applying means capable of applying a magnetic field to the manipulation tube to move the magnetic particles in the longitudinal direction of the tube.

Abstract translation: 本发明提供了一种小型和低运行成本的装置，其能够在执行一系列所有期望的操作的同时尽可能地最小化污染源的产生。 一种用于操纵操作管中的目标部件的装置，包括：操作管，其包括具有可选地可关闭的开口端的管，用于在一端提供含有目标部件的样品，在另一端封闭端，并且操作 介质容纳在管中并具有在管的纵向方向上多层的凝胶层和水性液体层; 应运送目标组分的磁性颗粒; 以及能够向操作管施加磁场以使磁性粒子沿着管的长度方向移动的磁场施加装置。

公开(公告)号：US09475062B2

公开(公告)日：2016-10-25

申请号：US14418447

申请日：2013-12-16

Applicant: SHOUNAN ENGINEERING INC.

Inventor： Masaji Sazawa

IPC: B03C1/12 ,  B03C1/28 ,  B03C1/033 ,  C02F1/48 ,  B24B55/03

CPC classification number: B03C1/12 ,  B03C1/0332 ,  B03C1/0335 ,  B03C1/286 ,  B03C1/288 ,  B03C2201/18 ,  B03C2201/20 ,  B24B55/03 ,  C02F1/481 ,  C02F1/488 ,  C02F2201/002 ,  C02F2201/48

Abstract: A magnetic inline filter is provided. A piston rod of a fluid cylinder is retracted to the top to locate an inner circumferential surface side magnet and an outer circumferential surface side magnet in filtration positions opposed to a space. In this state, a solenoid of a changeover valve is actuated to shut off a discharge port. A coolant is introduced into the space from an introduction port in the vicinity of the lower end of an outer pipe. Since a magnetic field in a radiation direction is intense, chips in the coolant are attracted to wall surfaces on both sides of the space and the coolant is filtrated. When the supply of the coolant is continued, the chips attracted to the wall surfaces are accumulated and bridged. As a result, since the coolant passes through gaps of the bridged chips, it is possible to perform precise filtration.

Abstract translation: 提供磁性在线滤波器。 流体缸的活塞杆缩回到顶部，以将内圆周表面侧磁体和外圆周表面磁体定位在与空间相对的过滤位置中。 在这种状态下，切换阀的螺线管被致动以关闭排出口。 冷却剂从外管附近的导入口引入空间。 由于辐射方向上的磁场强烈，所以冷却剂中的碎屑被吸引到空间的两侧的壁表面，并且冷却剂被过滤。 当冷却剂的供应持续时，吸引到壁表面的碎屑被积聚和桥接。 结果，由于冷却剂通过桥接芯片的间隙，因此可以进行精确的过滤。

公开(公告)号：US09393565B2

公开(公告)日：2016-07-19

申请号：US14487580

申请日：2014-09-16

Applicant: GEN-PROBE INCORPORATED

Inventor： Norbert D. Hagen ,  Byron J. Knight ,  David Opalsky

IPC: B03C1/06 ,  B01L3/00 ,  G01N35/00 ,  B03C1/033 ,  B03C1/28 ,  B65B3/04 ,  B03C1/12 ,  B03C1/14 ,  B01L9/00 ,  B25J11/00

CPC classification number: B01L3/52 ,  B01L3/561 ,  B01L9/52 ,  B01L2300/0609 ,  B01L2300/12 ,  B03C1/0332 ,  B03C1/12 ,  B03C1/14 ,  B03C1/28 ,  B03C1/286 ,  B03C1/288 ,  B03C2201/18 ,  B03C2201/26 ,  B25J11/00 ,  B65B3/04 ,  C12N15/1013 ,  G01N35/0098 ,  Y10T29/49815

Abstract: Methods, systems, and apparatus are provided for automated isolation of selected analytes, to which magnetically-responsive solid supports are bound, from other components of a sample. An apparatus for performing an automated magnetic separation procedure includes a mechanism for effecting linear movement of a magnet between operative and non-operative positions with respect to a receptacle device. A receptacle holding station within which a receptacle device may be temporarily stored prior to moving the receptacle to the apparatus for performing magnetic separation includes magnets for applying a magnetic field to the receptacle device held therein, thereby drawing at least a proton of the magnetically-responsive solid supports out of suspension before the receptacle device is moved to the magnetic separation station. An automated receptacle transport mechanism moves the receptacle devices between the apparatus for performing magnetic separation and the receptacle holding station.

公开(公告)号：US20160001299A1

公开(公告)日：2016-01-07

申请号：US14322549

申请日：2014-07-02

Applicant: Brent JOHNS

Inventor： Brent JOHNS

IPC: B03C1/30

CPC classification number: B03C1/12 ,  B03B5/26 ,  B03B7/00 ,  B03C1/0332 ,  B03C2201/18 ,  B03C2201/20

Abstract: An apparatus includes a placer-gold processing system, including: (A) an upstream section; (B) a gold-concentrator assembly being configured to be in fluid communication with the upstream section; (C) a gold-detection assembly being configured to be in fluid communication with the gold-concentrator assembly; and (D) a magnetite-separator assembly being configured to be in fluid communication with the gold-concentrator assembly.

Abstract translation: 一种装置，包括：镀金处理系统，包括：（A）上游段; （B）配置为与上游部分流体连通的金浓缩器组件; （C）金检测组件，其被配置为与所述金浓缩器组件流体连通; 和（D）磁铁矿分离器组件，其被配置成与所述集中金属组件流体连通。

公开(公告)号：US20150174730A1

公开(公告)日：2015-06-25

申请号：US14561022

申请日：2014-12-04

Applicant: Kinik Company

Inventor： Tian-Yeu WU

IPC: B24B53/017 ,  B03C1/02

CPC classification number: B24B53/017 ,  B03C1/0332 ,  B03C1/12 ,  B03C1/16 ,  B03C2201/20

Abstract: The present invention relates to a low magnetic chemical mechanical polishing conditioner, comprising a substrate; a bonding layer disposed on the substrate; and a plurality of abrasive particles placed on the bonding layer, and the abrasive particles are placed on the substrate by the bonding layer; wherein the abrasive particles are screened into a non-magnetic content and a low magnetic content through a magnetic separation device. Therefore, the abrasive particles used in the low magnetic chemical mechanical polishing conditioner of the present invention are non-magnetic abrasive particles perfectly to avoid influence of polishing performance due to magnetic abrasive particles.

Abstract translation: 本发明涉及一种低磁性化学机械抛光调理剂，其包含基材; 设置在所述基板上的接合层; 以及多个磨料颗粒放置在粘合层上，并且磨料颗粒通过粘结层放置在基底上; 其中所述研磨颗粒通过磁分离装置被筛选成非磁性含量和低磁性含量。 因此，本发明的低磁性化学机械抛光调理剂中使用的研磨颗粒是非磁性研磨颗粒，其完美地避免了由于磁性研磨颗粒引起的抛光性能的影响。

公开(公告)号：US09016478B2

公开(公告)日：2015-04-28

申请号：US14236800

申请日：2012-07-30

Applicant: Rudolf Böhnlein ,  Argun Gökpekin ,  Andreas Lekscha ,  Frank Schmidt ,  Ralph Oliver Schmidt ,  Bernd Zehentbauer

Inventor： Rudolf Böhnlein ,  Argun Gökpekin ,  Andreas Lekscha ,  Frank Schmidt ,  Ralph Oliver Schmidt ,  Bernd Zehentbauer

IPC: B03C1/00 ,  B03C1/14 ,  B03C1/12

CPC classification number: B03C1/145 ,  B03C1/12 ,  B03C1/14 ,  B03C2201/20 ,  B03C2201/24

Abstract: A magnetic drum separator (2), with a drum (6) rotatable about a rotational axis (4), a magnet arrangement (10) of a plurality of magnets (12) arranged in the interior (8) of the drum (6), a separation zone (18) in the exterior space (14) of the drum (6); a feed material (22) flows through the separation zone (18) and is there separable with the aid of a magnetic field (26) generated by the magnet arrangement (10), into a waste stream (30) and a recyclable material stream (28). A relative position (R) of at least one of the magnets (12) relative to the rotational axis (4) can be varied. A nominal magnitude (S) for a process value (78) on the drum separator (2) that is influenced by the separation behavior (32) is specified. At least one measurement device (74) detects an actual magnitude (I) of the process value (78), and a controller (82), which changes the relative position (R) of the at least one of the magnets (12), whereby the actual magnitude (I) is controlled to approach the nominal magnitude (S).

Abstract translation: 一个磁鼓分离器（2），具有围绕旋转轴线（4）旋转的滚筒（6），布置在滚筒（6）的内部（8）中的多个磁体（12）的磁体布置（10） ，在所述滚筒（6）的外部空间（14）中的分离区（18）; 进料材料（22）流过分离区（18），并且借助于由磁体装置（10）产生的磁场（26）可分离成废料流（30）和可再循环材料流 28）。 磁体（12）中的至少一个相对于旋转轴线（4）的相对位置（R）可以变化。 指定受分离行为（32）影响的鼓分离器（2）上的过程值（78）的标称量值（S）。 至少一个测量装置（74）检测过程值（78）的实际大小（I），以及改变至少一个磁体（12）的相对位置（R）的控制器（82） 由此控制实际幅度（I）以接近标称幅度（S）。

公开(公告)号：US20150027933A1

公开(公告)日：2015-01-29

申请号：US14500584

申请日：2014-09-29

Applicant: GEN-PROBE INCORPORATED

Inventor： Christopher B. DAVIS ,  Norbert D. HAGEN ,  James T. TUGGLE

IPC: B03C1/28 ,  B03C1/14 ,  B03C1/12

CPC classification number: B01L3/52 ,  B01L3/561 ,  B01L9/52 ,  B01L2300/0609 ,  B01L2300/12 ,  B03C1/0332 ,  B03C1/12 ,  B03C1/14 ,  B03C1/28 ,  B03C1/286 ,  B03C1/288 ,  B03C2201/18 ,  B03C2201/26 ,  B25J11/00 ,  B65B3/04 ,  C12N15/1013 ,  G01N35/0098 ,  Y10T29/49815

Abstract: A system for separating an analyte from other components of a sample contained in a receptacle, where the system includes a receptacle holding station and a magnetic separation station. The receptacle holding station is configured to receive and hold a receptacle and includes one or more magnets positioned to apply a magnetic field to the contents of the receptacle. When present in the receptacle holding station, a receptacle remains stationary relative to the one or more magnets. The magnetic separation station includes one or more magnets and is constructed and arranged to perform a magnetic separation procedure on the contents of a receptacle transported from the receptacle holding station to the magnetic separation station by an automated receptacle transport. The magnetic separation procedure includes isolating an analyte immobilized on a magnetically-responsive solid support within the receptacle and removing other components of the sample from the receptacle. The magnetic separation station is configured to provide relative movement between the receptacle and the one or more magnets after the receptacle is transported to the magnetic separation station.

Abstract translation: 用于将分析物与包含在容器中的样品的其它组分分离的系统，其中所述系统包括容器保持站和磁分离站。 容器保持站被配置为容纳和保持插座，并且包括一个或多个定位成将磁场施加到容器的内容物上的磁体。 当存在于容器保持站中时，容器相对于一个或多个磁体保持静止。 磁分离站包括一个或多个磁体，并被构造和布置成对通过自动插座传送从容器保持站传送到磁分离站的容器的内容物执行磁分离程序。 磁分离程序包括将固定在磁反应性固体支持物上的分析物分离在容器内并从容器中除去样品的其它组分。 磁性分离台构造成在容器被传送到磁分离站之后，在容器和一个或多个磁体之间提供相对运动。