| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 41 | 双轴拉伸吹塑成形瓶体成形用的合成树脂预塑件 | CN01805268.1 | 2001-12-20 | CN100411841C | 2008-08-20 | 秋山善男; 德田博昭; 毒岛真; 小盐秀一; 佐佐木正昭 |
| 提供一种瓶体,所述瓶体将具有叠层结构的吹塑成形预塑件(1’)的扩径筒部(4’)向下方扩径,通过利用型坯(P)吹塑成形底壳部(7’),将成形该底壳部(7’)的部分构成扩径变形的形状,在从与瓶颈环(3)对向的位置附近起直至扩径筒部(4’)的上端部范围内的任意位置的内周面部分上形成向下方扩径的扩径阶梯部(3’),或者/以及在圆筒部(5’)的下端部,将该圆筒部(5’)的直径向下方扩径作为扩径下端部(6’),通过把包含底壳部(7’)的下端部的整体制成鼓起很大的形状,防止从与瓶颈环(3)对向的位置附近起直至扩径筒部(4’)的上端部的部分处或者/以及在封合部(8’)处发生厚度堆积,提高整个厚度精度,借此获得没有外观形状畸变并具有叠层结构的瓶体。 | ||||||
| 42 | 热塑性弹性体的薄壁封端管形物品的制造方法 | CN02140302.3 | 1994-11-25 | CN1193868C | 2005-03-23 | R·G·米勒; W·C·米勒; O·T·坦科维茨 |
| 本文公开了插塞助推拉制薄壁、封端热塑性弹性体管形物品的方法,还公开了所用的热塑性弹性体和装置。按照本方法,系同时采用可伸入模子空腔(5)的插塞(6)和加在预型件两面的变化的气压差,来使被拉制物品的塑变流斜着沿轴线方向伸入管形模子的全长而远离模子壁。当被拉制物品基本上达到管形模子全长时,模子就被抽空,该物品最终就抵住模子壁而成形。这种物品通常是用作避孕套或手指套。 | ||||||
| 43 | 双轴拉伸吹塑成形瓶体成形用的合成树脂预塑件 | CN01805268.1 | 2001-12-20 | CN1404434A | 2003-03-19 | 秋山善男; 德田博昭; 毒岛真; 小盐秀一; 佐佐木正昭 |
| 提供一种瓶体,所述瓶体将具有叠层结构的吹塑成形预塑件(1’)的扩径筒部(4’)向下方扩径,通过利用型坯(P)吹塑成形底壳部(7’),将成形该底壳部(7’)的部分构成扩径变形的形状,在从与瓶颈环(3)对向的位置附近起直至扩径筒部(4’)的上端部范围内的任意位置的内周面部分上形成向下方扩径的扩径阶梯部(3’),或者/以及在圆筒部(5’)的下端部,将该圆筒部(5’)的直径向下方扩径作为扩径下端部(6’),通过把包含底壳部(7’)的下端部的整体制成鼓起很大的形状,防止从与瓶颈环(3)对向的位置附近起直至扩径筒部(4’)的上端部的部分处或者/以及在封合部(8’)处发生厚度堆积,提高整个厚度精度,借此获得没有外观形状畸变并具有叠层结构的瓶体。 | ||||||
| 44 | 复杂组合制品精确预成型的方法 | CN96197361.7 | 1996-09-17 | CN1198701A | 1998-11-11 | 约翰尼·保罗·让德罗 |
| 为纤维预型的装配提供一种装置和方法,用一个具有目标部件形状的成型模具和一个或多个辅助定位模具,放置在成型模具上,模拟一个平面形状。定位模具有多个向上伸出的定位销,使数个薄片装配成一个垂直的堆迭,用定位销保证片间精确定位。装配后,薄片被联接到装配件的指定部分且固定在位,撤下辅助模具,薄片在模具表面上成型。在自动化工艺中该装置和方法在装配及成型过程中把薄片保持在位,保证再生产。 | ||||||
| 45 | 热塑性弹性体的薄壁封端管形物品的制造方法 | CN94194855.2 | 1994-11-25 | CN1143345A | 1997-02-19 | R·G·米勒; W·C·米勒; O·T·坦科维茨 |
| 本文公开了插塞助推拉制薄壁、封端热塑性弹性体管形物品的方法,还公开了所用的热塑性弹性体和装置。按照本方法,系同时采用可伸入模子空腔(5)的插塞(6)和加在预型件两面的变化的气压差,来使被拉制物品的塑变流斜着沿轴线方向伸入管形模子的全长而远离模子壁。当被拉制物品基本上达到管形模子全长时,模子就被抽空,该物品最终就抵住模子壁而成型。这种物品通常是用作避孕套或手指套。 | ||||||
| 46 | 制造发泡网状聚合物材料制品的方法及制成的产品 | CN95191568.1 | 1995-11-10 | CN1141610A | 1997-01-29 | R·O·奥利沃希尔瓦 |
| 制造发泡网状聚合物材料制品的方法及所得到的产品的发明专利,其中,由在网化和发泡方法之前的聚合物材料的预模塑方法提供了通过预模塑部件的连结硫化生产多于一种以上颜色、密度和硬度的聚合物材料的可能性。 | ||||||
| 47 | Preform design for lightweight container | US15059379 | 2016-03-03 | US10022894B2 | 2018-07-17 | Michael T. Lane; Theodore F. Eberle; Terry D. Patcheak; James Stelzer |
| A preform configured to form a container by stretch blow molding. A finish portion is at a first end of the preform, and is a container finish. A tip portion is at a second end of the preform opposite to the first end, and is configured to form a container base and a container heel. The shoulder portion is adjacent to the finish portion and is between the finish portion and the tip portion. The shoulder portion is configured to form a container shoulder. The body portion is between the shoulder portion and the tip portion, and is configured to form a container body. The outer surface includes a first flat portion and a second flat portion at the tip portion. The first flat portion extends at a first angle and the second flat portion extends at a second angle that is different than the first angle. | ||||||
| 48 | BLADE COMPRISING LANDS WITH A STIFFENER | US15569665 | 2016-04-26 | US20180119550A1 | 2018-05-03 | Caroline Jacqueline Denise BERDOU; Thomas Alain DE GAILLARD |
| A preform for a turbine engine blade, the preform comprising a main fiber preform obtained by three-dimensional weaving and comprising a first longitudinal segment suitable for forming a blade root (21), a second longitudinal segment extending the first longitudinal segment upwards, and suitable for forming an airfoil portion (22), and a first transverse segment extending transversely from the junction between the first and second longitudinal segments, and suitable for forming a first platform (23), wherein the preform also includes at least one stiffener (40) fitted on the main fiber preform along at least a portion of the distal edge of the first transverse segment. | ||||||
| 49 | PROCESS AND APPARATUS FOR PRODUCING FIBER-REINFORCED THERMOPLASTIC RESIN TAPE | US15503857 | 2015-08-17 | US20170252988A1 | 2017-09-07 | Naoyuki TASHIRO; Takayasu FUJIURA; Kazuya TAKAMURA; Seiji ZENKE |
| Provided are a process and an apparatus for producing a fiber-reinforced thermoplastic resin tape, the process and the apparatus being capable of preventing fiber cut from occurring at the start of production of the fiber-reinforced thermoplastic resin tape. The provided process includes a resin impregnation step of opening a fiber bundle and impregnating the fiber bundle with molten thermoplastic resin and a through-nozzle passing step of passing the fiber bundle having undergone the resin impregnation step through a slit formed in a nozzle. The through-nozzle passing step includes setting, at the start of production, a gap dimension of the slit to a dimension larger than a normal dimension and changing the gap dimension of the slit to the normal dimension when a predetermined condition is satisfied, after the production start. | ||||||
| 50 | NANOCOMPOSITE MICROCAPSULES FOR SELF-HEALING OF COMPOSITE ARTICLES | US15309038 | 2015-04-30 | US20170100902A1 | 2017-04-13 | Ramazan Asmatulu; Vamsidhar Reddy Patlolla |
| Nanocomposite microcapsules for self-healing of composites. The nanocomposite microcapsules comprise a urea-formaldehyde shell encompassing a liquid core of polymerizable healing agent. The microcapsules further comprise nanoparticulates encompassed in the core and also present on the outer surface of the microcapsule shell. Self-healing composites with the nanocomposite microcapsules embedded in the composite polymer matrix are also described. Methods of making and using the same are also disclosed. | ||||||
| 51 | ELECTROSPINNING OF PTFE WITH HIGH VISCOSITY MATERIALS | US15209808 | 2016-07-14 | US20170096755A1 | 2017-04-06 | Bruce L. Anneaux; Robert L. Ballard; David P. Garner |
| An improved process for forming a PTFE mat is described. The process includes providing a dispersion with PTFE, a fiberizing polymer and a solvent wherein said dispersion has a viscosity of at least 50,000 cP. An apparatus is provided which comprises a charge source and a target a distance from the charge source. A voltage source is provided which creates a first charge at the charge source and an opposing charge at the target. The dispersion is electrostatically charged by contact with the charge source. The electrostatically charged dispersion is collected on the target to form a mat precursor which is heated to remove the solvent and the fiberizing polymer thereby forming the PTFE mat. | ||||||
| 52 | Plural blow utilization of counter stretch rod and/or base pushup | US14358122 | 2012-11-13 | US09522508B2 | 2016-12-20 | Bradley Wilson; Peter Bates; Frederick C. Beuerle; George David Lisch; Reinhard C. J. Luchies; Luke A. Mast |
| A molding system for molding a container includes a first blow mold operable for blow molding a first form of the container and a second blow mold operable for blow molding a second form of the container. The system further includes a counter stretch rod and/or a base pushup operable for reducing a height of the first form of the container before blow molding the second form of the container. A corresponding method of forming a container is also disclosed. | ||||||
| 53 | Method for producing a toothbrush handle having an inner cavity | US13683655 | 2012-11-21 | US09510669B2 | 2016-12-06 | Matthew Lloyd Newman; Li Wen; Andreas Birk; Andreas Bresselschmidt; Andrew Joseph Horton; Stephen Alan Houghton; Siegfried Kurt Hustedt; Scott Andrew Jackson; Jochen Erich Kawerau; Ralph Edwin Neufarth; Ulrich Pfeifer; Bradley John Phillips; Hansjoerg Reick; Richard Darren Satterfield; Heidrun Annika Schmelcher; Franziska Schmid; Jens Uwe Stoerkel; Andrew M. Uhe; George Michael West; Tilmann Winkler; Christopher Thomas Ryan |
| Methods of producing toothbrush handles having an inner cavity are provided. | ||||||
| 54 | Preform Design For Lightweight Container | US15059379 | 2016-03-03 | US20160257029A1 | 2016-09-08 | Michael T. LANE; Theodore F. EBERLE; Terry D. PATCHEAK; James STELZER |
| A preform configured to form a container by stretch blow molding. A finish portion is at a first end of the preform, and is a container finish. A tip portion is at a second end of the preform opposite to the first end, and is configured to form a container base and a container heel. The shoulder portion is adjacent to the finish portion and is between the finish portion and the tip portion. The shoulder portion is configured to form a container shoulder. The body portion is between the shoulder portion and the tip portion, and is configured to form a container body. The outer surface includes a first flat portion and a second flat portion at the tip portion. The first flat portion extends at a first angle and the second flat portion extends at a second angle that is different than the first angle. | ||||||
| 55 | PEROXIDE CROSS-LINKING AND HIGH TEMPERATURE MELTING | US15030206 | 2014-10-16 | US20160250779A1 | 2016-09-01 | Orhun K. Muratoglu; Ebru Oral |
| Methods of making oxidation and wear resistant polymeric materials using peroxide cross-linking and high temperature melting process are disclosed. A multiple step procedure for enabling the manufacturing of such material without size limitations is also disclosed. | ||||||
| 56 | PLATED TUBULAR LATTICE STRUCTURE | US14903305 | 2014-07-09 | US20160145850A1 | 2016-05-26 | Grant O. Cook; James T. Roach |
| A plated tubular lattice structure is described. The plated tubular lattice structure may comprise a backbone structure which may include a plurality of axial posts and a plurality of pyramidal structures extending laterally from the axial posts and connecting the axial posts at nodes. The plated tubular lattice structure may further comprise a metal plating layer plated on an outer surface of the backbone structure. | ||||||
| 57 | METHOD OF PRODUCING REINFORCING FIBER SHEET | US14769148 | 2014-04-16 | US20160001464A1 | 2016-01-07 | Tamotsu Suzuki; Yasumoto Noguchi |
| A method produces a reinforcing fiber sheet in which a plurality of bundles of reinforcing fibers lined up into one direction to form a plane are adhered to one another through a binder in an amount far smaller than that of the bundles. This method includes step (a) of placing a plurality of reinforcing fibers each having any length at any position on a flat plate, and fixing the reinforcing fibers onto the flat plate, step (b) of placing a binder onto the reinforcing fibers to be adhered onto the fibers, and step (c) of separating the reinforcing fibers from the flat plate. | ||||||
| 58 | PLASTIC AEROSOL CONTAINER AND METHOD OF MANUFACTURE | US13562546 | 2012-07-31 | US20130037580A1 | 2013-02-14 | Ralph ARMSTRONG; Keith J. Barker; Tapan Y. Patel |
| Plastic aerosol container having a thermally crystallized neck finish configured to receive an aerosol valve assembly and an expanded strain oriented aerosol container body integral with the neck finish. A junction between the thermally crystallized neck finish and the strain oriented container body defines a pull point at which strain orientation begins. | ||||||
| 59 | ELECTROSPINNING OF PTFE WITH HIGH VISCOSITY MATERIALS | US13446300 | 2012-04-13 | US20130023175A1 | 2013-01-24 | Bruce L. Anneaux; Robert Ballard; David P. Garner |
| An improved process for forming a PTFE mat is described. The process includes providing a dispersion with PTFE, a fiberizing polymer and a solvent wherein said dispersion has a viscosity of at least 50,000 cP. An apparatus is provided which comprises a charge source and a target a distance from the charge source. A voltage source is provided which creates a first charge at the charge source and an opposing charge at the target. The dispersion is electrostatically charged by contact with the charge source. The electrostatically charged dispersion is collected on the target to form a mat precursor which is heated to remove the solvent and the fiberizing polymer thereby forming the PTFE mat. | ||||||
| 60 | Collabsible Bottle, Method Of Manufacturing A Blank For Such Bottle And Beverage-Filled Bottle Dispensing System | US13379655 | 2010-06-21 | US20120097634A1 | 2012-04-26 | John Thomas Riedl |
| The present invention concerns a double-skinned inflatable bottle blank and its method of manufacturing which comprises: (i) stacking two sheets of liquid impermeable, flexible foil material, preferably in coplanar arrangement; (ii) blanking the sheets to create respective, preferably shape-congruent blanks having each a contoured perimeter edge; (iii) bonding the two blanks along joining seams that follow the contoured perimeter edges, but for at one or more inflation locations, thereby to define a double skinned blank into which an inflating fluid can be introduced through the inflation location; (iv) additionally bonding the two blanks at a plurality of discrete stiffening seams which are arranged in a predetermined grid or pattern thereby defining a grid-work of intersecting, inflatable stiffener structures in at least such part of the double skinned blank which will provide an upstanding peripheral wall of the bottle when erected through inflation; (v) folding the double skinned blank; and (vi) selectively bonding together portions of the joined perimeter edge of the double skinned blank, but for at a predetermined filling/dispensing location, to define a double-skinned, inflatable bottle blank with an internal cavity surrounded by a bottom wall for standing the bottle upright, said peripheral wall and a top wall, the filling/dispensing location located preferentially in the top wall such as to define a dispensing orifice for filling and dispensing liquid into and from the internal cavity, the inflatable stiffener structures providing an exoskeleton about the internal cavity when inflated. | ||||||
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