| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 1 | 预成型体的制造装置及制造方法以及通过该方法制造的预成型体 | CN201280004519.6 | 2012-02-14 | CN103298593A | 2013-09-11 | 樋野丰和; 山崎真明; 木部隆造 |
| 本发明涉及预成型体的制造装置、预成型体的制造方法、及通过该方法制造的预成型体,所述预成型体的制造装置的特征在于:将附着有以热塑性树脂作为主成分的固着材料的增强纤维基材多片层叠而成的层叠体,利用由彼此相对的模构成的赋形模通过加热赋形为规定形状,由此制造用于RTM成型的预成型体,仅在第一模上设置加热机构,并且第二模的至少与所述增强纤维基材接触的接触面由导热率低于第一模的材料形成。本发明提供能够将放热抑制在低水平、提高加热效率从而实现节能化、即使是赋形成复杂的形状的预成型体也能够尺寸精度良好地制作、能够容易地制造用于RTM成型的预成型体的、装置以及方法、通过该方法制造的预成型体。 | ||||||
| 2 | 预成型体的制造装置及制造方法以及通过该方法制造的预成型体 | CN201280004519.6 | 2012-02-14 | CN103298593B | 2016-01-27 | 樋野丰和; 山崎真明; 木部隆造 |
| 本发明涉及预成型体的制造装置、预成型体的制造方法、及通过该方法制造的预成型体,所述预成型体的制造装置的特征在于:将附着有以热塑性树脂作为主成分的固着材料的增强纤维基材多片层叠而成的层叠体,利用由彼此相对的模构成的赋形模通过加热赋形为规定形状,由此制造用于RTM成型的预成型体,仅在第一模上设置加热机构,并且第二模的至少与所述增强纤维基材接触的接触面由导热率低于第一模的材料形成。本发明提供能够将放热抑制在低水平、提高加热效率从而实现节能化、即使是赋形成复杂的形状的预成型体也能够尺寸精度良好地制作、能够容易地制造用于RTM成型的预成型体的、装置以及方法、通过该方法制造的预成型体。 | ||||||
| 3 | Fabrication, methods, apparatuses, and systems for ultra-compliant probes for neural and other tissues | US13680794 | 2012-11-19 | US09241651B2 | 2016-01-26 | Gary K. Fedder; Burak Ozdoganlar; Peter J. Gilgunn |
| Methods, systems and apparatuses of ultra-miniature, ultra-compliant probe arrays that allows for design flexibility to match the stiffness of the tissue it is being applied to, such as the brain tissue, in all three axes (x, y and z), with interconnect cross section smaller than cell dimensions. Stiffness matching requires specific geometric and fabrication approaches, commonly leading to ultra-thin probe wires. Sizing of the electrodes for specific cell dimensions reduces glial formation. Further reduction in stiffness is obtained by incorporating different geometric features to the electrode, such as meandering the electrode wires. The small thickness and geometric features of the wires commonly result in very high compliance. To enable effective insertion of the probes to the tissue, the present invention uses stiff biodisolvable and/or biodegradable polymers, including single use or combinations of carboxymethyl cellulose, polyvinylpyrrolidone, polyvinyl alcohol, maltose, other sugar molecules, polylactic acid and its co-polymers. | ||||||
| 4 | SEALING APPARATUS FOR CRYOPRESERVATION BAG | US14787406 | 2015-02-25 | US20160304227A1 | 2016-10-20 | Yasuo KUROSAKI; Katsuhiko UEDA; Kimitoshi SATO |
| There is provided a sealing apparatus for a cryopreservation bag, with which a sealing treatment of an inlet/outlet of the cryopreservation bag is carried out automatically and anyone can safely and properly carry out the sealing treatment.The sealing apparatus includes: a bag clamping device 56; a laser device 57; and a scanning structure 58 for moving the bag clamping device 56, for example. The bag clamping device 56 includes a fixed pinching block 67, a movable pinching block 69, and a clamp actuator 70. The laser device 57 includes a laser oscillator 104 and a condensing lens 107. The fixed pinching block 67 includes a block base 73, a heat radiator 74, and a heat radiator holder 75. An infrared laser beam is radiated to a sealed portion 55 of the bag to form a seal bead 125 for sealing in a state in which the sealed portion 55 is pinched and fixed by the heat radiator 74 and the movable pinching block 69 and while the bag clamping device 56, for example, is moved by the scanning structure 58. | ||||||
| 5 | FABRICATION, METHODS, APPARATUSES, AND SYSTEMS FOR ULTRA-COMPLIANT PROBES FOR NEURAL AND OTHER TISSUES | US14962016 | 2015-12-08 | US20160128636A1 | 2016-05-12 | Gary K. Fedder; Burak Ozdoganlar; Peter J. Gilgunn |
| Methods, systems and apparatuses of ultra-miniature, ultra-compliant probe arrays that allows for design flexibility to match the stiffness of the tissue it is being applied to, such as the brain tissue, in all three axes (x, y and z), with interconnect cross section smaller than cell dimensions. Stiffness matching requires specific geometric and fabrication approaches, commonly leading to ultra-thin probe wires. Sizing of the electrodes for specific cell dimensions reduces glial formation. Further reduction in stiffness is obtained by incorporating different geometric features to the electrode, such as meandering the electrode wires. The small thickness and geometric features of the wires commonly result in very high compliance. To enable effective insertion of the probes to the tissue, the present invention uses stiff biodisolvable and/or biodegradable polymers, including single use or combinations of carboxymethyl cellulose, polyvinylpyrrolidone, polyvinyl alcohol, maltose, other sugar molecules, polylactic acid and its co-polymers. | ||||||
| 6 | FABRICATION, METHODS, APPARATUSES, AND SYSTEMS FOR ULTRA-COMPLIANT PROBES FOR NEURAL AND OTHER TISSUES | US13680794 | 2012-11-19 | US20130131482A1 | 2013-05-23 | Gary K. Fedder; Burak Ozdoganlar; Peter J. Gilgunn |
| Methods, systems and apparatuses of ultra-miniature, ultra-compliant probe arrays that allows for design flexibility to match the stiffness of the tissue it is being applied to, such as the brain tissue, in all three axes (x, y and z), with interconnect cross section smaller than cell dimensions. Stiffness matching requires specific geometric and fabrication approaches, commonly leading to ultra-thin probe wires. Sizing of the electrodes for specific cell dimensions reduces glial formation. Further reduction in stiffness is obtained by incorporating different geometric features to the electrode, such as meandering the electrode wires. The small thickness and geometric features of the wires commonly result in very high compliance. To enable effective insertion of the probes to the tissue, the present invention uses stiff biodisolvable and/or biodegradable polymers, including single use or combinations of carboxymethyl cellulose, polyvinylpyrrolidone, polyvinyl alcohol, maltose, other sugar molecules, polylactic acid and its co-polymers. | ||||||
| 7 | プリフォームの製造装置および製造方法 | JP2012511078 | 2012-02-14 | JP5733306B2 | 2015-06-10 | 樋野 豊和; 山崎 真明; 木部 隆造 |
| 8 | プリフォームの製造装置および製造方法ならびにその方法により製造されたプリフォーム | JP2012511078 | 2012-02-14 | JPWO2012114933A1 | 2014-07-07 | 豊和 樋野; 山崎 真明; 真明 山崎; 隆造 木部 |
| 熱可塑性樹脂を主成分とする固着材を付着させた強化繊維基材を複数枚積層した積層体を、互いに対向する型から構成される賦形型で加熱を介して所定形状に賦形することにより、RTM成形に用いるプリフォームを製造する装置であって、第1の型のみに加熱機構を設けるとともに、第2の型の少なくとも前記強化繊維基材と接触する接触面が第1の型より熱伝導率の低い材料で形成されていることを特徴とするプリフォームの製造装置、プリフォームの製造方法、およびその方法により製造されたプリフォーム。放熱を小さく抑え加熱効率を上げて省エネルギー化が可能であり、複雑な形状に賦形されるプリフォームであっても寸法精度よく作製することが可能な、RTM成形に用いるプリフォームを容易に製造できる装置および方法、その方法により製造されたプリフォームを提供する。 | ||||||
| 9 | PREFORM FABRICATION APPARATUS, FABRICATION METHOD, AND PREFORM FABRICATED WITH SAME METHOD | EP12749542 | 2012-02-14 | EP2679366A4 | 2017-01-25 | HINO TOYOKAZU; YAMASAKI MASAAKI; KIBE RYUZO |
| A manufacturing apparatus and manufacturing method of a preform to be used for RTM forming, and preform manufactured by the method, wherein a layered body consisting of a plurality of layered reinforcing-fiber base materials to which a fixing agent consisting primarily of a thermoplastic resin is attached is formed into a predetermined shape as heated in a forming mold consisting of molds facing to each other, characterized in that only the first mold is provided with a heating mechanism and a contact face of the second mold contacting the reinforcing-fiber base material is made of a material which is less thermally conductive than the first mold. Provided is manufacturing apparatus and manufacturing method of preform, and preform manufactured by the method, wherein the energy saving can be achieved with low heat dissipation and high heating efficiency, and even a preform formed into a complicated shape can surely and easily be manufactured to be used for RTM (Resin Transfer Molding) forming method with a high dimension accuracy. | ||||||
| 10 | PREFORM FABRICATION APPARATUS, FABRICATION METHOD, AND PREFORM FABRICATED WITH SAME METHOD | EP12749542.2 | 2012-02-14 | EP2679366A1 | 2014-01-01 | HINO Toyokazu; YAMASAKI Masaaki; KIBE Ryuzo |
A manufacturing apparatus and manufacturing method of a preform to be used for RTM forming, and preform manufactured by the method, wherein a layered body consisting of a plurality of layered reinforcing-fiber base materials to which a fixing agent consisting primarily of a thermoplastic resin is attached is formed into a predetermined shape as heated in a forming mold consisting of molds facing to each other, characterized in that only the first mold is provided with a heating mechanism and a contact face of the second mold contacting the reinforcing-fiber base material is made of a material which is less thermally conductive than the first mold. Provided is manufacturing apparatus and manufacturing method of preform, and preform manufactured by the method, wherein the energy saving can be achieved with low heat dissipation and high heating efficiency, and even a preform formed into a complicated shape can surely and easily be manufactured to be used for RTM (Resin Transfer Molding) forming method with a high dimension accuracy. |
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| 11 | EPOXY MOLD MAKING AND MICROMILLING FOR MICROFLUIDICS | US15503360 | 2015-08-28 | US20170225363A1 | 2017-08-10 | Daniel Konstantinou; Alwin Wan; Tal Rosenzweig; Amir Sadri; Nenad Kircanski; Edmond Young |
| A method for efficiently manufacturing and fabricating microfluidic chips, where a base mold is formed to have positive-relief features used to cast an intermediary template chip with negative-relief features having dimensions of a scale in the micron range. The intermediary template chip is used to case a production mold, which is formed of a reinforced epoxy resin that, once hardened into a solid epoxy member, can withstand the structural pressures of a CNC machining system. The production mold can be refined by a CNC machining, where the refined production mold is then used to cast production chips to be used as microfluidic chips. | ||||||
| 12 | MOLDING APPARATUS, MOLDED ARTICLES, AND METHODS OF MOLDING | US14852078 | 2015-09-11 | US20150375463A1 | 2015-12-31 | W Sidney DuBinion |
| A mold assembly having a reversibly pressurized inner membrane disposed within the molding cavity is used to mold thermoplastic or thermoset articles. The use of the pressurized inner membrane enables the molding to be carried out below the melt temperature of a thermoplastic in some embodiments. The mold assembly and methods of molding enable the formation of molded articles, including complex articles, with improved properties compared to articles formed using conventional apparatuses and methods. | ||||||
| 13 | METHOD OF MANUFACTURING OPTICAL FILM FOR REDUCING COLOR SHIFT, ORGANIC LIGHT-EMITTING DISPLAY APPARATUS USING OPTICAL FILM FOR REDUCING COLOR SHIFT, AND METHOD OF MANUFACTURING THE SAME | US14549800 | 2014-11-21 | US20150144918A1 | 2015-05-28 | Eun-hyoung CHO; Woong KO; Jae-kwan KIM; Chang-youl MOON; Hong-shik SHIM; In-kyeong YOO; Chul-ho JEONG |
| An optical film manufacturing method includes forming a master in which a shape corresponding to a plurality of micro-lens patterns is engraved, forming a low refractive index pattern layer in which the plurality of micro-lens patterns are formed, by using the master, forming a high refractive index material layer that has a higher refractive index than a refractive index of the low refractive index pattern layer, and imprinting the low refractive index pattern layer on the high refractive index material layer to form a high refractive index pattern layer, on a first surface of a substrate. | ||||||
| 14 | MANUFACTURING APPARATUS AND METHODS OF MANUFACTURING PREFORMS, AND PREFORMS MANUFACTURED BY SAME METHOD | US14001262 | 2012-02-14 | US20130328243A1 | 2013-12-12 | Toyokazu Hino; Masaaki Yamasaki; Ryuzo Kibe |
| A manufacturing apparatus of a preform to be used for an RTM forming, wherein a layered body consisting of a plurality of layered reinforcing-fiber base materials to which a fixing agent consisting primarily of a thermoplastic resin is attached is formed by heating into a predetermined shape, comprising a forming mold consisting of a first mold and a second mold facing each other, wherein, only the first mold is provided with a heating mechanism and a contact face of the second mold contacting the reinforcing-fiber base material is made of a material which is less thermally conductive than the first mold., | ||||||
| 15 | APPARATUS FOR SEALING CRYOPRESERVATION BAG | EP15831901 | 2015-02-25 | EP3181463A4 | 2018-04-04 | KUROSAKI YASUO; UEDA KATSUHIKO; SATO KIMITOSHI |
| There is provided a sealing apparatus for a cryopreservation bag, with which a sealing treatment of an inlet/outlet of the cryopreservation bag is carried out automatically and anyone can safely and properly carry out the sealing treatment. The sealing apparatus includes: a bag clamping device 56; a laser device 57; and a scanning structure 58 for moving the bag clamping device 56, for example. The bag clamping device 56 includes a fixed pinching block 67, a movable pinching block 69, and a clamp actuator 70. The laser device 57 includes a laser oscillator 104 and a condensing lens 107. The fixed pinching block 67 includes a block base 73, a heat radiator 74, and a heat radiator holder 75. An infrared laser beam is radiated to a sealed portion 55 of the bag to form a seal bead 125 for sealing in a state in which the sealed portion 55 is pinched and fixed by the heat radiator 74 and the movable pinching block 69 and while the bag clamping device 56, for example, is moved by the scanning structure 58. | ||||||
| 16 | PREFORM FABRICATION METHOD | EP12749542.2 | 2012-02-14 | EP2679366B1 | 2018-04-04 | HINO Toyokazu; YAMASAKI Masaaki; KIBE Ryuzo |
| A manufacturing apparatus and manufacturing method of a preform to be used for RTM forming, and preform manufactured by the method, wherein a layered body consisting of a plurality of layered reinforcing-fiber base materials to which a fixing agent consisting primarily of a thermoplastic resin is attached is formed into a predetermined shape as heated in a forming mold consisting of molds facing to each other, characterized in that only the first mold is provided with a heating mechanism and a contact face of the second mold contacting the reinforcing-fiber base material is made of a material which is less thermally conductive than the first mold. Provided is manufacturing apparatus and manufacturing method of preform, and preform manufactured by the method, wherein the energy saving can be achieved with low heat dissipation and high heating efficiency, and even a preform formed into a complicated shape can surely and easily be manufactured to be used for RTM (Resin Transfer Molding) forming method with a high dimension accuracy. | ||||||
| 17 | 색변화 저감용 광학 필름의 제조방법, 색변화 저감용 광학필름이 적용된 유기발광 표시장치 및 이의 제조방법 | KR1020130143152 | 2013-11-22 | KR1020150059494A | 2015-06-01 | 조은형; 고웅; 김재관; 문창렬; 심홍식; 유인경; 정철호 |
| 광학필름제조방법은다수의마이크로렌즈패턴에대응하는형상이음각된마스터를형성하는단계; 상기마스터를이용하여, 상기다수의마이크로렌즈패턴이형성된저굴절률패턴층을형성하는단계; 기판상의제1면에, 상기저굴절률패턴층의굴절률보다큰 굴절률을가지는고굴절률물질층을형성하고, 상기저굴절률패턴층을상기고굴절률물질층에임프린트하여고굴절률패턴층을형성하는단계;를포함한다. | ||||||
| 18 | 프리폼의 제조 장치 및 제조 방법, 및 이 방법에 의해 제조된 프리폼 | KR1020137023923 | 2012-02-14 | KR1020140006023A | 2014-01-15 | 히노,도요카즈; 야마사키,마사키; 기베,류조 |
| 본 발명은 열가소성 수지를 주성분으로 하는 고착재를 부착시킨 강화 섬유 기재를 복수매 적층한 적층체를, 서로 대향하는 형으로 구성되는 부형형으로 가열을 통해 소정 형상으로 부형함으로써, RTM 성형에 사용하는 프리폼을 제조하는 장치이며, 제1형에만 가열 기구를 설치함과 동시에, 제2형의 적어도 상기 강화 섬유 기재와 접촉하는 접촉면이 제1형보다 열전도율이 낮은 재료로 형성되어 있는 것을 특징으로 하는 프리폼의 제조 장치, 프리폼의 제조 방법 및 이 방법에 의해 제조된 프리폼을 제공한다.
또한, 본 발명은, 방열을 작게 억제하여 가열 효율을 높여 에너지 절약화가 가능하며, 복잡한 형상으로 부형되는 프리폼이라도 양호한 치수 정밀도로 제조하는 것이 가능한, RTM 성형에 사용하는 프리폼을 용이하게 제조할 수 있는 장치 및 방법, 이 방법에 의해 제조된 프리폼을 제공한다. |
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| 19 | 마그네슘합금 파이프를 이용한 롤러 및 롤러 제조방법 | KR1020110035992 | 2011-04-19 | KR101064646B1 | 2011-09-15 | 곽재경 |
| 본 발명은 마그네슘합금 파이프를 이용한 롤러 및 롤러 제조방법에 관한 것으로서, 마그네슘합금 파이프를 사용하여 롤러를 제조함으로써, 가격이 저렴하면서도 중량이 가볍고 강도가 우수한 롤러를 제조할 수 있도록 하는 것을 목적으로 한다.
이러한 목적을 달성하기 위한 본 발명은, 일정 길이로 형성되는 파이프와, 상기 파이프의 양측에 삽입되고 용접되는 축부재와, 상기 파이프의 외주면에 형성되는 코팅부를 포함하는 롤러에 있어서, 상기 파이프는, 보강용 선형돌기가 내벽에 간격을 두고 형성되는 마그네슘합금 파이프로 제조되고; 상기 축부재는, 마그네슘합금 봉재로 형성되고 외주면 나사부와 축 둘레에 다수의 쐐기용 볼트홀이 더 형성되는 것을 특징으로 한다. |
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| 20 | MOLDING APPARATUS, MOLDED ARTICLES, AND METHODS OF MOLDING | PCT/US2014030973 | 2014-03-18 | WO2014153323A1 | 2014-09-25 | DUBINION W SIDNEY |
| A mold assembly having a reversibly pressurized inner membrane disposed within the molding cavity is used to mold thermoplastic or thermoset articles. The use of the pressurized inner membrane enables the molding to be carried out below the melt temperature of a thermoplastic in some embodiments. The mold assembly and methods of molding enable the formation of molded articles, including complex articles, with improved properties compared to articles formed using conventional apparatuses and methods. | ||||||
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