公开(公告)号：US20170232684A1

公开(公告)日：2017-08-17

申请号：US15518910

申请日：2015-10-02

Applicant: KAO CORPORATION

Inventor： Tadanori YOSHIMURA ,  Takuma KIMURA

IPC: B29C67/00 ,  C08L33/12 ,  C08K7/14 ,  C08L67/04 ,  C08K3/34 ,  C08K3/40 ,  B33Y70/00 ,  C08L55/02

CPC classification number: C08L55/02 ,  B29C64/106 ,  B29C64/118 ,  B29C64/40 ,  B29C67/00 ,  B29K2055/02 ,  B29K2067/046 ,  B33Y10/00 ,  B33Y70/00 ,  C08F220/04 ,  C08F220/14 ,  C08F220/18 ,  C08F222/02 ,  C08K3/34 ,  C08K3/40 ,  C08K7/14 ,  C08K2201/003 ,  C08K2201/004 ,  C08L33/12 ,  C08L67/04 ,  C08L2205/16 ,  C08F220/06 ,  C08F2220/1825 ,  C08F212/08 ,  C08F222/22

Abstract: The soluble material for three-dimensional modeling of the present invention is a soluble material for three-dimensional modeling that is used as a material of a support material that supports a three-dimensional object when manufacturing the three-dimensional object with a fused deposition modeling type 3D printer. The soluble material for three-dimensional modeling contains at least one polymer and at least one filler. In the soluble material for three-dimensional modeling, the filler is a fibrous filler having a fiber length of 0.02 μm to 1,000 μm and a fiber diameter of 0.0001 μm to 20 μm and/or a flat filler having a particle size of 0.1 μm to 20 μm and a thickness of 0.01 μm to 10 μm. The content of the filler is 0.01 part by mass to 200 parts by mass with respect to 100 parts by mass of the polymer. According to the present invention, foaming and a decrease of the accuracy of a three-dimensional object can be suppressed even when the soluble material for three-dimensional modeling is used in manufacture of the three-dimensional object with a 3D printer after being exposed to high humidity.

公开(公告)号：US20170001919A1

公开(公告)日：2017-01-05

申请号：US15221903

申请日：2016-07-28

Applicant: NGK INSULATORS, LTD.

Inventor： Hiroharu KOBAYASHI

IPC: C04B38/00 ,  C04B35/634 ,  C04B35/638 ,  F01N13/08 ,  C04B35/626 ,  C09K21/02 ,  F01N13/14 ,  C04B35/48 ,  C04B38/06

CPC classification number: C04B38/009 ,  C01P2006/14 ,  C01P2006/17 ,  C04B35/48 ,  C04B35/488 ,  C04B35/622 ,  C04B35/62625 ,  C04B35/6264 ,  C04B35/6342 ,  C04B35/638 ,  C04B38/068 ,  C04B2111/00405 ,  C04B2111/28 ,  C04B2235/3244 ,  C04B2235/60 ,  C04B2235/6025 ,  C04B2235/656 ,  C04B2235/6567 ,  C04B2235/661 ,  C04B2235/775 ,  C04B2235/9607 ,  C04B2237/341 ,  C04B2237/348 ,  C04B2237/58 ,  C08K7/24 ,  C08K2201/004 ,  C08K2201/016 ,  C09K21/02 ,  F01N13/08 ,  F01N13/14 ,  F02F1/4264 ,  F05C2251/048 ,  F05C2253/12 ,  Y10T428/2982 ,  Y10T428/2991 ,  C04B20/0008 ,  C04B20/1029 ,  C04B38/0074 ,  C04B38/06

Abstract: Provided is a porous plate-shaped filler that can be used as a material for a heat-insulation film having excellent heat insulation performance. In a porous plate-shaped filler 1 having a plate shape, an aspect ratio is 3 or higher, a minimum length is 0.5 to 50 μm, and an overall porosity is 20 to 90%, and the porosity is lower in the circumferential part than in the center part. When this porous plate-shaped filler 1 of the present invention is contained in a heat-insulation film, the infiltration of a matrix into the filler is reduced, and thus the thermal conductivity can be lowered. Therefore, even a thin heat-insulation film can have a greater heat-insulation effect than before.

Abstract translation: 提供一种多孔板形填料，其可以用作具有优异绝热性能的绝热膜材料。 在板状的多孔板状填料1中，纵横比为3以上，最小长度为0.5〜50μm，整体孔隙率为20〜90％，圆周方向的孔隙率低于 在中心部分。 当本发明的多孔板状填料1被包含在绝热膜中时，基质向填料中的渗透减少，因此导热性可以降低。 因此，即使薄的绝热膜也能够比以前具有更大的绝热效果。

公开(公告)号：US20160340503A1

公开(公告)日：2016-11-24

申请号：US15111130

申请日：2014-07-30

Applicant: KOREA CONTAINER POOL CO., LTD.

Inventor： Yang Jae Shin ,  Yun Suk Cho

IPC: C08L23/08 ,  B29C45/00 ,  B29B9/10 ,  C08L23/12 ,  C08L23/06

CPC classification number: C08L23/0807 ,  B29B9/10 ,  B29C45/0001 ,  B29K2023/0633 ,  B29K2023/12 ,  B29K2105/08 ,  B29K2309/08 ,  C08J5/04 ,  C08K7/14 ,  C08K2201/004 ,  C08L23/04 ,  C08L23/06 ,  C08L23/10 ,  C08L23/12 ,  C08L2207/066

Abstract: Disclosed is a composition containing at least two types of resins and long glass fibers. The composition includes: a resin blend including at least two types of unit resins; long glass fibers having a length of 10 mm or more; and a rubber-based resin, wherein the long glass fibers and the rubber-based resin are used in an amount of 3-30 parts by weight and 0.5-25 parts by weight, respectively, based on 100 parts by weight of the resin blend.

Abstract translation: 公开了含有至少两种树脂和长玻璃纤维的组合物。 该组合物包括：包含至少两种类型的单元树脂的树脂共混物; 长度为10mm以上的长玻璃纤维; 和橡胶基树脂，其中长玻璃纤维和橡胶基树脂的使用量分别为3-30重量份和0.5-25重量份，基于100重量份的树脂共混物 。

公开(公告)号：US20160280888A1

公开(公告)日：2016-09-29

申请号：US14900394

申请日：2014-06-24

Applicant: ALTACHEM NV

Inventor： Jean-Marie POPPE ,  Jordi DEMEY

IPC: C08K7/10 ,  C08K5/092 ,  B65D83/48 ,  C08K9/10

CPC classification number: C08K7/10 ,  B65D83/46 ,  B65D83/48 ,  C08K3/34 ,  C08K5/092 ,  C08K9/10 ,  C08K2201/004 ,  C08K2201/016 ,  C08L23/04 ,  C08L23/06 ,  C08L23/08

Abstract: The present invention relates to a valve member for a dispenser valve for foam products, and in particular for a dispenser valve for polyurethane foam container, comprising a valve member that is moveable relative to a sealing. It also relates to such a dispenser valve and to a foam container.In order to provide alternative materials for valve members, it is proposed according to the invention that the valve member is made of plastic material filled with basalt particles in an amount between 1% and 60% by weight.It has been surprisingly found that valve members made of plastic filled with basalt particles in these amounts show improved properties, such as strength and abrasion rates, compared to non-filled plastics and compared to glass-filled plastics.

Abstract translation: 已经令人惊奇地发现，与未填充的塑料相比，填充有这些量的玄武岩颗粒的塑料制成的阀构件显示出与未填充的塑料相比具有改进的性能，例如强度和磨损率，并且与玻璃填充塑料相比。

公开(公告)号：US20160227644A1

公开(公告)日：2016-08-04

申请号：US14911707

申请日：2014-08-12

Applicant: DENKA COMPANY LIMITED

Inventor： Hideki HIROTSURU ,  Shuhei NONAKA ,  Toshikatsu MITSUNAGA ,  Koki IKARASHI ,  Kouji MIYATA ,  Taiki NISHI ,  Saori INOUE ,  Fumiya KOBAYASHI

IPC: H05K1/02 ,  H05K1/09 ,  H05K1/03

CPC classification number: H05K1/0271 ,  C08K7/00 ,  C08K2003/385 ,  C08K2201/004 ,  H05K1/0203 ,  H05K1/0306 ,  H05K1/0353 ,  H05K1/0373 ,  H05K1/09 ,  H05K3/022 ,  H05K3/38 ,  H05K2201/0104 ,  H05K2201/066

Abstract: A boron nitride/resin composite circuit board having high heat dissipation characteristics and high relyability is provided. A boron nitride/resin composite circuit board, including: a plate-shaped resin-impregnated boron nitride sintered body having a plate thickness of 0.2 to 1.5 mm, the plate-shaped resin-impregnated boron nitride sintered body including 30 to 85 volume % of a boron nitride sintered body having boron nitride particles bonded three-dimensionally, the boron nitride particles having an average long diameter of 5 to 50 μm, and 70 to 15 volume % of a resin; and a metal circuit adhered onto both principal planes of the plate-shaped resin-impregnated boron nitride sintered body, the metal circuit being copper or aluminum, wherein: a ratio of a linear thermal expansion coefficient in a plane direction of the resin-impregnated boron nitride sintered body at 40 to 150° C. (CTE1) and a linear thermal expansion coefficient of the metal circuit at 40 to 150° C. (CTE2) (CTE1/CTE2) is 0.5 to 2.0.

Abstract translation: 提供具有高散热特性和高可靠性的氮化硼/树脂复合电路板。 一种氮化硼/树脂复合电路板，包括：板厚为0.2〜1.5mm的板状树脂浸渍氮化硼烧结体，含有30〜85体积％的板状树脂浸渍氮化硼烧结体 具有三维结合的氮化硼颗粒的氮化硼烧结体，平均长径为5〜50μm的氮化硼颗粒和70〜15体积％的树脂; 以及附着在板状树脂浸渍氮化硼烧结体的两个主平面上的金属电路，金属电路为铜或铝，其中：树脂浸渍硼的平面方向的线性热膨胀系数的比例 40℃〜150℃（CTE1）的金属电路的线性热膨胀系数（CTE2）（CTE1 / CTE2）为40〜150℃。

公开(公告)号：US20160194461A1

公开(公告)日：2016-07-07

申请号：US14911419

申请日：2015-02-06

Applicant: TEIJIN LIMITED

Inventor： Shuhei SUZUKI ,  Takaya FUJII ,  Hodaka YOKOMIZO ,  Hidenori AOKI

IPC: C08J5/04

CPC classification number: C08J5/042 ,  C08J2377/06 ,  C08K7/06 ,  C08K2201/004 ,  C08K2201/014 ,  C08L101/00

Abstract: There is provided a plate-shaped carbon fiber reinforced molding material comprising a thermoplastic resin, carbon fibers (A) and carbon fibers (B), wherein: i) the carbon fibers (A) have fiber lengths ranging from 0.01 mm to less than 3 mm, ii) the carbon fibers (B) have fiber lengths ranging from 3 mm to less than 100 mm, iii) 1.0

Abstract translation: 提供了包含热塑性树脂，碳纤维（A）和碳纤维（B）的板状碳纤维增强模塑材料，其中：i）碳纤维（A）的纤维长度范围为0.01mm至小于3 mm，ii）碳纤维（B）的纤维长度为3mm至小于100mm，iii）满足1.0w / LnA <3，其中LwA和LnA是重均纤维长度和数均分子量 分别为碳纤维（A）的纤维长度，和iv）碳纤维（B）是二维随机取向的。

公开(公告)号：US09303137B2

公开(公告)日：2016-04-05

申请号：US13783295

申请日：2013-03-02

Applicant: ANF Technology Limited

Inventor： Ilya Grodnensky

IPC: C08J3/22 ,  C08K3/22 ,  C08K3/08 ,  C01F7/42 ,  C08J5/04

CPC classification number: C08K3/22 ,  C01F7/42 ,  C01P2004/03 ,  C01P2004/04 ,  C01P2004/16 ,  C08J5/005 ,  C08J5/044 ,  C08K3/08 ,  C08K7/08 ,  C08K2003/2227 ,  C08K2201/003 ,  C08K2201/004 ,  C08K2201/005 ,  C08K2201/011 ,  C30B25/005 ,  C30B29/20 ,  C30B29/62

Abstract: A method for producing a nanocomposite material reinforced by alumina Al2O3 nanofibers involving synthesizing the alumina Al2O3 nanofibers directly from a melt comprising molten metallic aluminum, the method comprising a controlled liquid phase oxidation of the melt, wherein the synthesized alumina Al2O3 nanofibers have a diameter between 3 and 45 nm and length of more than 100 nm and combining the synthesized alumina Al2O3 nanofibers with a polymer matrix to produce the nanocomposite material reinforced by the alumina Al2O3 nanofibers. The alumina Al2O3 nanofibers may be monocrystalline alumina Al2O3 nanofibers. The alumina Al2O3 nanofibers and the molecules of the polymer may be aligned.

Abstract translation: 一种由氧化铝Al2O3纳米纤维增强的纳米复合材料的制造方法，其包括直接由熔融金属铝的熔融物合成氧化铝Al 2 O 3纳米纤维，所述熔融金属铝的熔融控制液相氧化，其中合成的氧化铝Al 2 O 3纳米纤维的直径为3 和45nm，长度大于100nm，并将合成的氧化铝Al2O3纳米纤维与聚合物基体结合，生产由氧化铝Al2O3纳米纤维增强的纳米复合材料。 氧化铝Al2O3纳米纤维可以是单晶氧化铝Al2O3纳米纤维。 氧化铝Al2O3纳米纤维和聚合物的分子可以对齐。

公开(公告)号：US20150375051A1

公开(公告)日：2015-12-31

申请号：US14754180

申请日：2015-06-29

Applicant: Dunlop Sports Co., Ltd.

Inventor： Kazuyoshi SHIGA ,  Masanori TAGUCHI ,  Takahiro SHIGEMITSU ,  Hiroshi TADAOKA

IPC: A63B37/00 ,  C08K3/22 ,  C08K5/09 ,  C08K3/04 ,  C08K5/17

CPC classification number: A63B37/0049 ,  A63B37/0039 ,  A63B37/0043 ,  A63B37/0075 ,  C08K3/042 ,  C08K3/22 ,  C08K3/36 ,  C08K5/09 ,  C08K5/175 ,  C08K7/02 ,  C08K9/04 ,  C08K2003/2206 ,  C08K2003/2224 ,  C08K2003/2227 ,  C08K2003/2296 ,  C08K2201/003 ,  C08K2201/004 ,  C08K2201/016 ,  C08L23/0876

Abstract: An object of the present invention is to provide a golf ball exhibiting an excellent shot feeling and resilience, and a constituent material thereof. The present invention provides a golf ball resin composition having a bending stiffness (M3-12) ranging from 300 kgf/cm2 to 24,000 kgf/cm2 at a bending angle from 3° to 12°, a ratio (M3-12/M24-30) of the bending stiffness (M3-12) at the bending angle from 3° to 12° to a bending stiffness (M24-30) at a bending angle from 24° to 30° ranging from 0.20 to 2.00, and a slab hardness ranging from 30 to 65 in Shore D hardness.

Abstract translation: 本发明的目的是提供一种具有优异的拍摄感和弹性的高尔夫球及其构成材料。 本发明提供一种高折射率树脂组合物，其弯曲角度为3°至12°，弯曲刚度（M3-12）范围为300kgf / cm2至24,000kgf / cm2，比率（M3-12 / M24-30 ）弯曲角度为3°至12°的弯曲刚度（M3-12），弯曲刚度（M24-30）在弯曲角为24°至30°范围为0.20至2.00之间的弯曲刚度（M3-12） 从30到65的肖氏D硬度。

公开(公告)号：US09192912B1

公开(公告)日：2015-11-24

申请号：US13446775

申请日：2012-04-13

Applicant: David Mills ,  Yuri M. Lvov

Inventor： David Mills ,  Yuri M. Lvov

IPC: B01J20/16 ,  C08L33/12 ,  A61C5/08

CPC classification number: A61L24/0089 ,  A61C8/0012 ,  A61C8/0016 ,  B01J20/16 ,  C08K3/34 ,  C08K9/10 ,  C08K2201/003 ,  C08K2201/004 ,  C08K2201/011 ,  C08L33/12

Abstract: An augmented ceramic composite including aluminosilicate nanotubes may be added to a biocompatible polymer matrix. Aluminosilicate nanotubes have a surprisingly high biocompatibility, radio opaqueness, and suitability for storing therapeutic compounds for release over time. These surprising advantages make aluminosilicate nanotubes, such as halloysite nanotubes, a good candidate for use in various medical applications from bone and dental prosthetics to cancer treatment and prevention. Furthermore, unlike other additives, the addition of certain quantities of halloysite nanotubes increases the strength of the polymer matrix to which it is added.

Abstract translation: 包括铝硅酸盐纳米管的增强陶瓷复合材料可以加入到生物相容的聚合物基质中。 硅铝酸盐纳米管具有令人惊奇的高生物相容性，无线电不透明度和适用于随时间释放的治疗化合物的储存。 这些令人惊奇的优点使铝硅酸盐纳米管（如多水高岭土纳米管）成为用于从骨骼和牙科假肢到癌症治疗和预防的各种医学应用的良好候选物。 此外，与其他添加剂不同，加入一定量的多水高岭土纳米管增加了加入其中的聚合物基质的强度。

公开(公告)号：US20150259511A1

公开(公告)日：2015-09-17

申请号：US14729540

申请日：2015-06-03

Applicant: SUMITOMO RIKO COMPANY LIMITED

Inventor： Masayoshi Nakano ,  Junichiro Suzuki ,  Motoshige Hibino ,  Kei Okumura ,  Wakako Michiyama ,  Yasuhiro Komiya

IPC: C08K7/14 ,  B29C45/00

CPC classification number: C08K7/14 ,  B29C45/0001 ,  B29K2077/00 ,  B29K2309/08 ,  B29L2031/045 ,  B29L2031/06 ,  B29L2031/772 ,  C08G2261/342 ,  C08J5/043 ,  C08J2377/06 ,  C08K2201/004 ,  C08K2201/014 ,  C08L65/00 ,  C08L77/06 ,  C08L23/12

Abstract: A glass-fiber-reinforced thermoplastic resin molding product is provided, which has a ring-shaped structure, and includes a thermoplastic resin, and a fibrous filler dispersed in the thermoplastic resin. The fibrous filler includes: (A) 40 to 80% of glass fibers each having a length of at least 0.05 mm and less than 0.5 mm; (B) 15 to 40% of glass fibers each having a length of at least 0.5 mm and less than 1.0 mm; (C) 5 to 30% of glass fibers each having a length of at least 1.0 mm and less than 3.0 mm; and (D) at most 1% of glass fibers each having a length of at least 3.0 mm, based on the total number of fibers of the fibrous filler present in the molding product.

Abstract translation: 提供了一种玻璃纤维增​​强热塑性树脂成型体，其具有环状结构，并且包括热塑性树脂和分散在热塑性树脂中的纤维状填料。 纤维状填料包括：（A）40-80％的长度为至少0.05mm且小于0.5mm的玻璃纤维; （B）15〜40％的长度为0.5mm以上且小于1.0mm的玻璃纤维; （C）5〜30％的长度至少为1.0mm且小于3.0mm的玻璃纤维; 和（D）至少1％的玻璃纤维，其长度至少为3.0mm，基于模制产品中存在的纤维填料的总纤维数。