公开(公告)号：US20110003965A1

公开(公告)日：2011-01-06

申请号：US12826613

申请日：2010-06-29

Applicant: Jiang-Jen Lin ,  Wood-Hi Cheng ,  Yi-Fen Lan ,  Jin-Chen Chiu ,  Jhe-Wei Lin ,  Chia-Ming Chang

Inventor： Jiang-Jen Lin ,  Wood-Hi Cheng ,  Yi-Fen Lan ,  Jin-Chen Chiu ,  Jhe-Wei Lin ,  Chia-Ming Chang

IPC: C08G73/10

CPC classification number: C08L79/08 ,  B82Y30/00 ,  C08J3/2053 ,  C08J5/005 ,  C08J2379/08 ,  C08K3/041 ,  H05K9/009

Abstract: The present invention provides a complex including carbon nanotubes (CNT) and polyimide (PI), and a method for producing the same. The CNT-PI complex possesses good electromagnetic shielding effectiveness. The CNT-PI complex primarily includes polyimide and carbon nanotubes dispersed in the polyimide. The method for producing the CNT-PI complex first disperses carbon nanotubes in a solvent by adding a dispersant and using an ultrasonic oscillator. Then the carbon nanotubes dispersion is mixed with polyamic acid to give a CNT-PI dispersion. The CNT-PI dispersion is then dried to form a film or layer of the CNT-PI complex. The dispersant used in this invention is an ionic liquid including organic cations and inorganic anions. The produced CNT-PI complex presents better networked structures and electrical conductivity.

Abstract translation: 本发明提供了包含碳纳米管（CNT）和聚酰亚胺（PI）的复合物及其制造方法。 CNT-PI复合物具有良好的电磁屏蔽效果。 CNT-PI复合物主要包括分散在聚酰亚胺中的聚酰亚胺和碳纳米管。 CNT-PI络合物的制造方法首先通过添加分散剂并使用超声波振荡器将碳纳米管分散在溶剂中。 然后将碳纳米管分散体与聚酰胺酸混合，得到CNT-PI分散体。 然后将CNT-PI分散体干燥以形成CNT-PI复合物的膜或层。 用于本发明的分散剂是包括有机阳离子和无机阴离子的离子液体。 生产的CNT-PI复合物具有更好的网络结构和导电性。

公开(公告)号：US20080096468A1

公开(公告)日：2008-04-24

申请号：US11772914

申请日：2007-07-03

Applicant: Ying-Chien Tsai ,  Yu-Kuan Lu ,  Yu-Da Liu ,  Wood-Hi Cheng

Inventor： Ying-Chien Tsai ,  Yu-Kuan Lu ,  Yu-Da Liu ,  Wood-Hi Cheng

IPC: B24B1/00

CPC classification number: B24B19/226 ,  B24B5/14 ,  B24B19/16

Abstract: A fiber grinding process includes: contacting an end of the optical fiber with a grinding surface in such a manner that a central axis of the optical fiber at the end is inclined to the grinding surface; rotating the optical fiber about the central axis; and changing a contact pressure between the end of the optical fiber and the grinding surface by applying a variable torque while rotating the optical fiber. A substantially cone-shaped end face with a substantially elliptic cross-section may be produced. A fiber grinding apparatus is also disclosed.

Abstract translation: 纤维研磨方法包括：使光纤的端部与研磨表面接触，使得光纤的端部的中心轴线与研磨表面倾斜; 围绕中心轴旋转光纤; 以及通过在旋转光纤的同时施加可变转矩来改变光纤端部与研磨表面之间的接触压力。 可以制造具有基本上椭圆形横截面的基本上锥形的端面。 还公开了一种纤维研磨装置。

公开(公告)号：US20070273056A1

公开(公告)日：2007-11-29

申请号：US11820213

申请日：2007-06-18

Applicant: Wood-Hi Cheng ,  Szu-Ming Yeh

Inventor： Wood-Hi Cheng ,  Szu-Ming Yeh

IPC: B29D11/00

CPC classification number: G02B6/4203 ,  B29D11/00663 ,  G02B6/262

Abstract: The present invention relates to a conical wedge-shaped lensed fiber and the method of making the same. The method comprises: (a) providing an optical fiber having a central axis and an end; (b) machining the end of the optical fiber to form a flat end face; (c) machining the end of the optical fiber to form a conical region; (d) machining one side of the conical region to form a flat first surface; (e) machining another side of the conical region to form a flat third surface, wherein the first surface and the third surface intersect at a intersecting line that is perpendicular to the central axis; and (f) fusing the intersecting line to form a lens. The method has simplified fabricating processes and need not to set up any particular angle of rotation of the fiber. Therefore, the fabricating time and cost are reduced, and the coupling efficiency of the lensed fiber is up to 90%.

公开(公告)号：US20070274631A1

公开(公告)日：2007-11-29

申请号：US11820212

申请日：2007-06-18

Applicant: Wood-Hi Cheng ,  Szu-Ming Yeh

Inventor： Wood-Hi Cheng ,  Szu-Ming Yeh

IPC: G02B6/32 ,  B29D11/00

CPC classification number: G02B6/4203 ,  B29D11/00663 ,  G02B6/262

Abstract: The present invention relates to a conical wedge-shaped lensed fiber and the method of making the same. The method comprises: (a) providing an optical fiber having a central axis and an end; (b) machining the end of the optical fiber to form a flat end face; (c) machining the end of the optical fiber to form a conical region; (d) machining one side of the conical region to form a flat first surface; (e) machining another side of the conical region to form a flat third surface, wherein the first surface and the third surface intersect at a intersecting line that is perpendicular to the central axis; and (f) fusing the intersecting line to form a lens. The method has simplified fabricating processes and need not to set up any particular angle of rotation of the fiber. Therefore, the fabricating time and cost are reduced, and the coupling efficiency of the lensed fiber is up to 90%.

公开(公告)号：US07295729B2

公开(公告)日：2007-11-13

申请号：US11183406

申请日：2005-07-18

Applicant: Wood-Hi Cheng ,  Szu-Ming Yeh

Inventor： Wood-Hi Cheng ,  Szu-Ming Yeh

IPC: G02B6/32 ,  G02B6/26 ,  G02B6/42

CPC classification number: G02B6/4203 ,  B29D11/00663 ,  G02B6/262

Abstract: The present invention relates to a conical wedge-shaped lensed fiber and the method of making the same. The method comprises: (a) providing an optical fiber having a central axis and an end; (b) machining the end of the optical fiber to form a flat end face; (c) machining the end of the optical fiber to form a conical region; (d) machining one side of the conical region to form a flat first surface; (e) machining another side of the conical region to form a flat third surface, wherein the first surface and the third surface intersect at a intersecting line that is perpendicular to the central axis; and (f) fusing the intersecting line to form a lens. The method has simplified fabricating processes and need not to set up any particular angle of rotation of the fiber. Therefore, the fabricating time and cost are reduced, and the coupling efficiency of the lensed fiber is up to 90%.

Abstract translation: 锥形透镜光纤及其制造方法技术领域本发明涉及锥形楔形透镜光纤及其制造方法。 该方法包括：（a）提供具有中心轴和端部的光纤; （b）加工光纤的端部以形成平坦的端面; （c）加工光纤的端部以形成圆锥形区域; （d）加工所述锥形区域的一侧以形成平坦的第一表面; （e）加工所述锥形区域的另一侧以形成平坦的第三表面，其中所述第一表面和所述第三表面在垂直于所述中心轴线的交叉线处相交; 和（f）将相交线熔合以形成透镜。 该方法简化了制造工艺，并且不需要设置任何特定的光纤旋转角度。 因此，制造时间和成本降低，并且透镜光纤的耦合效率高达90％。

公开(公告)号：US09445212B2

公开(公告)日：2016-09-13

申请号：US12050368

申请日：2008-03-18

Applicant: Lung-Tai Chen ,  Chun-Hsun Chu ,  Wood-Hi Cheng

Inventor： Lung-Tai Chen ,  Chun-Hsun Chu ,  Wood-Hi Cheng

IPC: H04R9/08 ,  H04R31/00 ,  H04R19/01

CPC classification number: H04R31/00 ,  H04R19/016

Abstract: A micro-electro-mechanical system (MEMS) microphone module and a manufacturing process thereof are described. A thickness of a transparent temporary cover plate temporarily disposed in a conventional plastic package structure is adjusted. After a mold for a plastic protector is formed, an UV ray is utilized to irradiate the mold to reduce adherence on the temporary cover plate and a back surface of the MEMS acoustic wave sensing chip. Then, the temporary cover plate is removed, and the left space left is the main source for the back-volume of the MEMS microphone. Finally, a tag is covered on the plastic protector, so as to define the whole back-volume and form a closed back-volume. In the above-mentioned process, the size of the back-volume is the same as an area of the whole MEMS microphone chip. In addition, the back-volume can be defined.

Abstract translation: 微机电系统（MEMS）麦克风模块及其制造过程被描述。 临时设置在传统的塑料封装结构中的透明临时盖板的厚度被调节。 在形成用于塑料保护器的模具之后，使用紫外线照射模具以减少临时盖板和MEMS声波感测芯片的背面的粘附。 然后，移除临时盖板，剩下的剩余空间是用于MEMS麦克风的后部体积的主要来源。 最后，在塑料保护器上覆盖一个标签，以便定义整个后部体积并形成封闭的后部体积。 在上述处理中，背面体积的大小与整个MEMS麦克风芯片的面积相同。 此外，可以定义后卷。

公开(公告)号：US20130248903A1

公开(公告)日：2013-09-26

申请号：US13424635

申请日：2012-03-20

Applicant: JAU-SHENG WANG ,  CHUN-CHIN TSAI ,  WEI-CHIH CHENG ,  SHUN-YUAN HUANG ,  WOOD-HI CHENG

Inventor： JAU-SHENG WANG ,  CHUN-CHIN TSAI ,  WEI-CHIH CHENG ,  SHUN-YUAN HUANG ,  WOOD-HI CHENG

IPC: H01L33/50

CPC classification number: H01L33/486 ,  H01L33/60 ,  H01L2924/0002 ,  H01L2933/0033 ,  H01L2924/00

Abstract: A light emitting diode package module structure comprises a LED module received in a reflection cup, a light transmitting color conversion member disposed on an annular surface of the reflection cup, a stationary package sleeved on the reflection cup in such a manner that the press portion of the stationary package is pressed against the light transmitting color conversion member, and the stop portions of the positioning legs of the stationary package are positioned against the bottom of the reflection cup. In this way, the light transmitting color conversion member is fixed to the reflection cup by the stationary package without the use of adhesive agents, which consequently simplifies the packaging procedure and reduces the package cost.

Abstract translation: 发光二极管封装模块结构包括容纳在反射杯中的LED模块，设置在反射杯的环形表面上的透光颜色转换构件，以这样的方式套在反射杯上的固定封装， 固定包装被压靠在透光颜色转换构件上，并且静止包装的定位腿的止动部分抵靠反射杯的底部定位。 以这种方式，透光颜色转换构件通过固定封装而不使用粘合剂固定到反射杯，这因此简化了封装程序并降低了封装成本。

公开(公告)号：US07494399B2

公开(公告)日：2009-02-24

申请号：US11772914

申请日：2007-07-03

Applicant: Ying-Chien Tsai ,  Yu-Kuan Lu ,  Yu-Da Liu ,  Wood-Hi Cheng

Inventor： Ying-Chien Tsai ,  Yu-Kuan Lu ,  Yu-Da Liu ,  Wood-Hi Cheng

IPC: B24B49/00

CPC classification number: B24B19/226 ,  B24B5/14 ,  B24B19/16

Abstract: A fiber grinding process includes: contacting an end of the optical fiber with a grinding surface in such a manner that a central axis of the optical fiber at the end is inclined to the grinding surface; rotating the optical fiber about the central axis; and changing a contact pressure between the end of the optical fiber and the grinding surface by applying a variable torque while rotating the optical fiber. A substantially cone-shaped end face with a substantially elliptic cross-section may be produced. A fiber grinding apparatus is also disclosed.

Abstract translation: 纤维研磨方法包括：使光纤的端部与研磨表面接触，使得光纤的端部的中心轴线与研磨表面倾斜; 围绕中心轴旋转光纤; 以及通过在旋转光纤的同时施加可变转矩来改变光纤端部与研磨表面之间的接触压力。 可以制造具有基本上椭圆形横截面的基本上锥形的端面。 还公开了一种纤维研磨装置。

公开(公告)号：US20070086714A1

公开(公告)日：2007-04-19

申请号：US11183406

申请日：2005-07-18

Applicant: Wood-Hi Cheng ,  Szu-Ming Yeh

Inventor： Wood-Hi Cheng ,  Szu-Ming Yeh

IPC: G02B6/02 ,  G02B6/26 ,  G02B6/42

CPC classification number: G02B6/4203 ,  B29D11/00663 ,  G02B6/262

Abstract: The present invention relates to a conical wedge-shaped lensed fiber and the method of making the same. The method comprises: (a) providing an optical fiber having a central axis and an end; (b) machining the end of the optical fiber to form a flat end face; (c) machining the end of the optical fiber to form a conical region; (d) machining one side of the conical region to form a flat first surface; (e) machining another side of the conical region to form a flat third surface, wherein the first surface and the third surface intersect at a intersecting line that is perpendicular to the central axis; and (f) fusing the intersecting line to form a lens. The method has simplified fabricating processes and need not to set up any particular angle of rotation of the fiber. Therefore, the fabricating time and cost are reduced, and the coupling efficiency of the lensed fiber is up to 90%.

公开(公告)号：US20050008309A1

公开(公告)日：2005-01-13

申请号：US10881482

申请日：2004-06-30

Applicant: Yu-Kuan Lu ,  Szu-Ming Yeh ,  Wood-Hi Cheng

Inventor： Yu-Kuan Lu ,  Szu-Ming Yeh ,  Wood-Hi Cheng

IPC: G02B6/255 ,  G02B6/42 ,  G02B6/02

CPC classification number: G02B6/4203 ,  G02B6/2552

Abstract: The present invention relates to a quadrangular-pyramid-shaped lensed fiber. One end of the fiber is ground to become quadrangular-pyramid-shaped. Small volume of the tip of the quadrangular-pyramid-shaped fiber is heated to form a semi-ellipsoidal microlens, thereby forming the quadrangular-pyramid-shaped lensed fiber. The advantage of the present invention is that the shape of the semi-ellipsoidal microlens can be controlled by adjusting the angles of the quadrangular-pyramid-shaped fiber according to the aspect ratio of the diode laser so as to enhance the coupling efficiency between an optical fiber and a diode laser.

Abstract translation: 本发明涉及一种四棱锥形透镜纤维。 纤维的一端被研磨成四角锥形。 将四边形棱锥形纤维的尖端的小体积加热以形成半椭圆形微透镜，由此形成四棱锥形透镜纤维。 本发明的优点在于，可以通过根据二极管激光器的纵横比调节四棱锥形光纤的角度来控制半椭圆形微透镜的形状，以提高光学器件之间的耦合效率 光纤和二极管激光器。