| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 121 | Method of manufacturing an article by molding | EP12159420.4 | 2012-03-14 | EP2639050A1 | 2013-09-18 | Lind, Soeren Oemann; Madsen, Finn Daugaard; Stege, Jason |
A method of manufacturing an article by molding is provided. The method comprises the steps of: |
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| 122 | BONDING METHOD OF RESIN MEMBER | EP08738677 | 2008-03-19 | EP2130665A4 | 2012-06-13 | SEKIHARA KANJI; UEHIRA MASAYOSHI |
| A method for bonding resin members by laser welding in which melting of a resin member can be prevented on the contact surface with a base or a tool used for bonding. In the bonding method, a resin member (1) is mounted on a base (3) and a surface of the base (3) in contact with the resin member (1) is an optical mirror surface. A surface of the resin member (1) is coated with a light absorbing agent (4), a resin member (2) is placed thereon and then a laser light (10) is irradiated from the resin member (2) side in order to melt the resin on the bonding surface of the resin member (1) and the resin member (2), thereby bonding the resin members together. The laser light (11) penetrated through the bonding surface reaches the contact surface where the resin member (1) and the base (3) are in contact with each other, and since the laser light (11) penetrates the bonding surface without being scattered or absorbed, melting of the resin member can be prevented. | ||||||
| 123 | Improved method and apparatus for shaping thermoplastic tubes | EP91310383.4 | 1991-11-11 | EP0486237B1 | 1995-01-18 | Bowkett, Trevor George |
| 124 | Improved method and apparatus for shaping thermoplastic tubes | EP91310383.4 | 1991-11-11 | EP0486237A1 | 1992-05-20 | Bowkett, Trevor George |
s7 A method of and apparatus for shaping thermoplastic tube (1) by external formers (5,6,7,8) uses pulsed emission of short wave infra-red radiation (33) to soften the thermoplastic material with the tube (1) held in the required configuration on the formers (5,6,7,8) followed by air cooling (33) to harden the thermoplastic material and retain the required configuration. A jig (3) for supporting the tube (1) in the desired configuration comprises a base table (4) on which the formers (5,6,7,8) are adjustably mounted for altering the desired configuration. |
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| 125 | METHOD AND DEVICE FOR PRODUCING A DOUBLE LENS FOR SAFETY GLASSES | PCT/EP2013058379 | 2013-04-23 | WO2013164223A3 | 2014-01-09 | SCHAEFER STEFAN; FRIEDLEIN UWE; TAEUBER MANFRED |
| The method is used for producing a double lens (2) for safety glasses. The double lens (2), comprising two individual lenses (13, 14) that are connected to one another, is integrally injection moulded from a plastic material and immediately ready for use, or immediately ready for an optional additional surface treatment step. During the injection moulding process, a first lens part zone (15) with a first optical function, a second lens part zone (16) with a second optical function different from the first optical function and a lens transition zone (17) between the first and second lens part zones (15, 16) with a continual transition from the first to the second optical function is produced in each individual lens (13, 14), which is associated with a respective eye of the wearer. During the injection moulding process, the double lens (2) is provided with an impact resistance of at least 45 m/s in accordance with the DIN EN 166 standard if the double lens (2) is intended for safety glasses or of at least 120 m/s if the double lens (2) is intended for a full view safety visor with a headband. | ||||||
| 126 | 압출 원료 공급 장치 및 이것을 이용한 광 전송체의 제조 방법 | KR1020117023202 | 2010-01-26 | KR101779213B1 | 2017-09-18 | 오까모또,다즈루; 요시다,히로쯔구; 고이께,야스히로 |
| 용융압출성형에서사용하는데 바람직한압출원료공급장치를제공함과동시에, 광신호의전달손실악화가매우적고, 압출성형법본래의생산성을겸비하는광 전송체의제조방법을제공한다. 압출원료공급장치(1)는냉각부(3) 및그 하방에연속되는가열용융부(4)를갖고원료로드(R)가수납되는수직형상의호퍼(2)와, 냉각부(3)를냉각하는냉각수단(5)과, 가열용융부(4)를가열하는전기히터(6)와, 가스압으로용융플라스틱(M)을순차적으로금형에공급하기위한가스가압수단(7)을구비하고있다. 가열용융부(4)는그 상측에있는냉각부(3)보다도내경이큰 원통형상으로형성되어있고, 용융된플라스틱(M)이가열용융부(4) 내에서넓어질수 있도록되어있다. 원료로드(R)의외주와용융플라스틱(M)의외주의사이가환상의가스가압면(7a)으로되어있다. | ||||||
| 127 | 소프트 몰드 및 그 제조방법, 소프트 몰드의 사용방법, 소프트몰드를 이용해 제조되는 광학필름 | KR1020110025295 | 2011-03-22 | KR1020120107656A | 2012-10-04 | 장원근; 김인선; 이기호; 조민두; 김혜미 |
| PURPOSE: A soft mold and a manufacturing method thereof, and a method using the soft mold are provided to easily transfer circular patterns on a film by using a soft mold in a simple process. CONSTITUTION: A soft mold(1) manufacturing method is as follows. A silicon master wafer(10) has optical patterns and directivity, and a molding liquid(20) is spread on a surface of the silicon master wafer(S2). A base material(30) for a soft mold is touched to the spread molding liquid and cured(S3). The cured molding liquid and base for the soft mold are separated from each other(S4). | ||||||
| 128 | 층상 제품의 형성방법 | KR1020067015072 | 2005-01-14 | KR101148420B1 | 2012-05-25 | 브리스토우폴안토니; 데이비스스코트마이클; 힙웰제스가이; 미어스란댈토드; 테우슈에리치오토 |
| 본 발명은 층상 제품의 형성방법에 관한 것이고, 이 방법은 기판 시트를 열성형하여 형상화된 기판을 형성하는 단계(이때, 상기 형상화된 기판은 형상화된 기판을 통해 진공이 인가되기에 충분한 공동률을 갖는 섬유-강화 플라스틱 물질이다); 형성된 형상화된 기판을 통해 진공을 인가하는 단계; 및 상기 형상화된 기판의 표면으로 필름층을 끌어당겨 층상 제품을 형성하는 단계를 포함한다. | ||||||
| 129 | 압출 원료 공급 장치 및 이것을 이용한 광 전송체의 제조 방법 | KR1020117023202 | 2010-01-26 | KR1020120001743A | 2012-01-04 | 오까모또,다즈루; 요시다,히로쯔구; 고이께,야스히로 |
| 용융 압출 성형에서 사용하는 데 바람직한 압출 원료 공급 장치를 제공함과 동시에, 광 신호의 전달 손실 악화가 매우 적고, 압출 성형법 본래의 생산성을 겸비하는 광 전송체의 제조 방법을 제공한다. 압출 원료 공급 장치(1)는 냉각부(3) 및 그 하방에 연속되는 가열 용융부(4)를 갖고 원료 로드(R)가 수납되는 수직 형상의 호퍼(2)와, 냉각부(3)를 냉각하는 냉각 수단(5)과, 가열 용융부(4)를 가열하는 전기 히터(6)와, 가스압으로 용융 플라스틱(M)을 순차적으로 금형에 공급하기 위한 가스 가압 수단(7)을 구비하고 있다. 가열 용융부(4)는 그 상측에 있는 냉각부(3)보다도 내경이 큰 원통 형상으로 형성되어 있고, 용융된 플라스틱(M)이 가열 용융부(4) 내에서 넓어질 수 있도록 되어 있다. 원료 로드(R)의 외주와 용융 플라스틱(M)의 외주의 사이가 환상의 가스 가압면(7a)으로 되어 있다.
|
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| 130 | 유브이 하드코팅을 이용한 인몰드 제품의 표면처리방법 | KR1020000007275 | 2000-02-16 | KR1020010083548A | 2001-09-01 | 김명준 |
| PURPOSE: A surface processing method for an in-mold product is provided to prevent the reflection of light and to improve the resistance against scratching and the quality of the surface by intensifying the hardness of the surface. CONSTITUTION: A surface processing method for an in-mold product comprises the steps of: printing a pattern(2) on the rear face of a film(1) and drying the film; firstly drying after screen-printing with UV(Ultraviolet) hard coat ink(3) on the front face of the printed film; secondly UV drying after forming the printed film; obtaining a desired part from the film by cutting; and obtaining a completed product by combining the printed film to the surface of an in-mold product. Herein, the surface hardness is increased. Therefore, resistance against scratching is high and coated state becomes even. | ||||||
| 131 | 열가소성 플라스틱 관을 성형하는 개선된 방법과 장치 | KR1019910019963 | 1991-11-11 | KR100165679B1 | 1999-03-20 | 트레버죠지보우케트 |
| 최소한 하나의 외부 성형기(5,6,7,8)위에 관(1)을 지지하면서 단파 적외선 방사로 관(1)을 가열하고 원하는 모양으로 관(1)을 만들도록 공기냉각하므로써 열가소성 플라스틱 관(1)을 성형하는 방법과 장치. | ||||||
| 132 | ACOUSTIC DAMPENING FOR A MECHANICAL DEVICE | PCT/US2010042764 | 2010-07-21 | WO2011011524A2 | 2011-01-27 | BODWELL JESSE T |
| A two-component elastomeric enclosure surrounding a mechanical device can effectively attenuate the noise and vibration associated with the device. The outer shell of the enclosure comprises a castable polyurethane elastomer, while the inner shell of the enclosure comprises polymeric foam. The inner foam layer of the enclosure can contact both vertical and horizontal surfaces of the enclosed device in order to immobilize it within the enclosure, and to enhance the dampening effect of the enclosure on acoustic and mechanical vibrations. The enclosure can act as a vertical and horizontal supporting structure for the enclosed mechanical device. The enclosure may in turn be fastenable to a housing or frame member via relatively stiff elastomeric bushings, pads or mounts, in order to further reduce the transmission of vibrations origination from the mechanical device. The enclosure can be molded in a two-stage pour -molding process using a cavity mold and two forming dies- one for each layer of the enclosure. The second stage of the molding process allows the inner foam layer to bond to the outer shell of the enclosure during the curing process, and to have inner dimensions that can make close contact with pre-determined portions of the device for which the enclosure is being produced. Highly customized cavity molds and forming dies can be created using rapid manufacturing or prototyping techniques. | ||||||
| 133 | METHODS OF FORMING A LAYERED ARTICLE | PCT/US2005001375 | 2005-01-14 | WO2005072934A3 | 2005-10-27 | BRISTOW PAUL ANTHONY; DAVIS SCOTT MICHAEL; HIPWELL JESSE GUY; MYERS RANDALL TODD; TEUTSCH ERICH OTTO |
| A method of forming a layered article, the method comprises thermoforming a substrate sheet to form a shaped substrate, wherein the shaped substrate is a fiber-reinforced plastic material having a void content sufficient to allow a vacuum to be applied through the shaped substrate; pulling a vacuum through the shaped substrate; and pulling a film layer onto a surface of the shaped substrate to form the layered article. | ||||||
| 134 | HOLLOW FIBER MEMBRANE REINFORCED WITH MONOFILAMENTS, AND METHOD FOR MANUFACTURING SAME | PCT/KR2012003189 | 2012-04-25 | WO2012148168A3 | 2013-03-28 | SEO CHANG MIN; LEE GYEONG MO |
| In order to solve problems of damage due to fibrils or lint in a hollow fiber membrane having multifilaments that arise in the prior art, the present invention provides a further improved hollow fiber membrane in which an open-type tubular knitwork using monofilaments is spirally manufactured and the resultant knitwork is embedded into a polymer resin. The open-type tubular knitwork is characterized in that it is weaved at a fixed angle by each monofilament so as to form either a rhomboid or a diamond shape. The monofilaments are weaved onto a plasticized cable to form the knitwork, and a polymer dope for the hollow fiber membrane is coated on the knitwork, such that the knitwork is embedded into the polymer, and then the dope is coagulated. Here, the plasticized cable determines the inner diameter of the hollow fiber membrane. The hollow fiber membrane, in which the open-type knitwork is embedded as described above, is expandable (extendable) in a longitudinal direction and is expandable in a radial direction, thereby enabling biaxial expansion. That is, the hollow fiber membrane is flexible in the radial direction as well as in the longitudinal direction. Due to the flexibility in the radial direction, the hollow fiber membrane can be backwashed at a higher pressure than can a hollow fiber membrane made using multifilaments, which is hardly expandable in the radial direction. Thus, manufacturing efficiency is improved. | ||||||
| 135 | METHODS AND SYSTEMS FOR USING ACTUATED SURFACE-ATTACHED POSTS FOR ASSESSING BIOFLUID RHEOLOGY | PCT/US2010040011 | 2010-06-25 | WO2010151780A2 | 2010-12-29 | SUPERFINE RICHARD; SPERO RICHARD CHASEN |
| Methods, systems, and computer readable media for using actuated surface-attached posts for assessing biofluid rheology are disclosed. According to one aspect, a method for testing properties of a biofluid specimen includes placing the specimen onto a micropost array having a plurality of microposts extending outwards from a substrate, wherein each micropost includes a proximal end attached to the substrate and a distal end opposite the proximal end, and generating an actuation force in proximity to the micropost array to actuate the microposts, thereby compelling at least some of the microposts to exhibit motion. The method further includes measuring the motion of at least one of the microposts in response to the actuation force and determining a property of the specimen based on the measured motion of the at least one micropost. | ||||||
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