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    • 5. 发明授权
    • Fin structure for fin tube heat exchanger
    • 散热片管式热交换器翅片结构
    • US08291724B2
    • 2012-10-23
    • US11989229
    • 2006-07-28
    • Naoki ShikazonoNobuhide KasagiYuji SuzukiYoshinori SuzueKenichi Morimoto
    • Naoki ShikazonoNobuhide KasagiYuji SuzukiYoshinori SuzueKenichi Morimoto
    • F25B39/02
    • F28F1/32F25B39/00
    • A heat exchanger has multiple laminated fins 30. Each fin 30 has multiple tops 34 and multiple bottoms 36 arranged to have a preset acute angle γ (for example, 30 degrees) to an air flow line at an air inlet and to make an air flow in a cavity region behind each of multiple heat transfer tubes 22a to 22c in an air flow direction at an air outlet. This design of the fins 30 produces effective secondary flows of the air to improve the heat transfer efficiency and makes an additional contribution to heat exchange, due to the air flow in the cavity region behind each of the heat transfer tubes 22a to 22c in the air flow direction. This arrangement effectively prevents separation of the air flow and a local speed increase of the air flow, while improving the overall heat exchange efficiency by production of the effective secondary flows of the air.
    • 热交换器具有多个层叠翅片30.每个翅片30具有多个顶部34和多个底部36,多个底部36布置成具有与进气口处的空气流动管线相同的预设锐角γ(例如30度),并且使空气流动 在空气出口处的空气流动方向上的多个传热管22a至22c中的每一个之后的腔区域中。 翅片30的这种设计产生有效的空气二次流以提高热传递效率,并且由于空气中的空气流动在空气中在空气中流动在空气中的每个传热管22a至22c的空气中 流向。 这种布置有效地防止空气流的分离和空气流的局部速度增加,同时通过产生有效的空气二次流来提高总的热交换效率。
    • 6. 发明申请
    • CELL SEPARATION DEVICE, CELL SEPARATION SYSTEM AND CELL SEPARATION METHOD
    • 细胞分离装置,细胞分离系统和细胞分离方法
    • US20110097793A1
    • 2011-04-28
    • US12994802
    • 2009-05-27
    • Yuji SuzukiNobuhide KasagiTakahiro NishimuraJunichi Miwa
    • Yuji SuzukiNobuhide KasagiTakahiro NishimuraJunichi Miwa
    • C12N5/02C12M1/00
    • C12M47/02G01N1/405G01N2015/1006
    • A cell separation device which can perform a continuous processing without bonding fluorescent molecules or magnetic particles to the surface of the cell membrane, a cell separation system, and a cell separation method, wherein when a sample cell suspension containing the desired target cells is supplied continuously from a sample inlet and physiological saline is supplied continuously from a physiological saline inlet, the sample cell suspension flows together with the physiological saline in a liquid flow path and an adsorption force acts on the target cells due to affinity bonding from the adsorbing portions of adsorbing regions in the form of strips formed in a planar wall portion. Since the adsorbing regions in the form of strips are disposed in an asymmetric fashion to the flow path direction of the liquid flow path, the adsorption force acting on the target cells has a constituent perpendicular to the flow path direction. As a result, the target cells shown in FIG. 1 collect on one side of the planar wall portion after flowing for a prescribed distance in the liquid flow path and can be separated continuously from the non-target constituents.
    • 可以在不将荧光分子或磁性粒子粘附到细胞膜表面的情况下进行连续处理的细胞分离装置,细胞分离系统和细胞分离方法,其中当连续供给包含所需靶细胞的样品细胞悬浮液时 从生理盐水入口连续供给来自样品入口的生理盐水,样品池悬浮液与生理盐水一起在液体流动路径中流动,并且吸附力由吸附的吸附部分的亲和键作用在靶细胞上 形成在平面壁部分中的带状形式的区域。 由于带状吸附区域以液态流路的流路方向为非对称的方式配置,所以作用在靶单元上的吸附力具有与流路方向垂直的构成。 结果,图1所示的靶细胞 1在液体流动路径中流动规定距离之后,在平面壁部分的一侧收集,并且可以与非目标成分连续分离。