子分类:
- B29L2031/001: .{异形构件,如梁,截面}
- B29L2031/04: .轴承
- B29L2031/06: .杆,如连杆{栏杆,木桩(轴入B29L2031/75;电线杆,桅杆,门柱B29L2031/766)}
- B29L2031/08: .转子、定子、风扇、涡轮机或类似装置的叶片,如螺旋桨
- B29L2031/10: .建筑构件,如砖、砌块、瓦、壁板、柱子、梁{(无框圆顶入B29L25/00,门入B29L2031/724)}
- B29L2031/12: .链条
- B29L2031/14: .过滤器{(滤光器入B29L2011/0066,筛或屏风入B29L2031/737)}
- B29L2031/16: .摩擦元件,例如制动器或离合器衬层
- B29L2031/18: .热交换器或其零件
- B29L2031/20: .燃料块,如核燃料元件
- B29L2031/22: .铰链{枢轴}
- B29L2031/24: .管接头或连接器(B29L31/26优先)
- B29L2031/26: .密封装置,如活塞或管接头的封装
- B29L2031/28: .工具,如餐具
- B29L2031/30: .车辆,如船或飞机,或其主体部件{(轮叶或叶片入B29L31/08,气囊入B29L2022/027)}
- B29L2031/32: .轮子、小齿轮、皮带轮、小脚轮或滚柱{轮辋(内管入B29L2023/245;齿轮入B29L2015/003;轮胎入B29L30/00)}
- B29L2031/34: .电气装置,如火花塞或其零件
- B29L2031/38: .扬声器纸盆;传声膜片
- B29L2031/40: .试样;{模型,例如汽车模型(人体模特入B29L2031/7028);探头}
- B29L2031/42: .刷子
- B29L2031/44: .家具或其零件
- B29L2031/46: .旋钮或手柄{推入式按钮,握把(用于服饰店的按钮入B29L19/00, 作为紧固件的压入式按钮入B29L2031/7282)}
- B29L2031/48: .服装服饰
- B29L2031/52: .运动设备;{游戏;娱乐用品};玩具(B29L31/54优先)
- B29L2031/54: .球类
- B29L2031/56: .瓶子、罐子或类似物的塞子或盖(例如瓶塞)
- B29L2031/58: .内饰或垫,如车内装饰或内部填料{(床垫,座垫入B29L2031/8178)}
- B29L2031/60: .多管状或多隔间制品,如蜂窝结构
- B29L2031/70: .{农业用途或农用设备}
- B29L2031/702: .{仿制品,如雕像,人体模特(医疗设备入B29L2031/753;模型入B29L31/40)}
- B29L2031/703: .{波纹管}
- B29L2031/704: .{线轴,卷轴}
- B29L2031/705: .{书籍,相册}
- B29L2031/706: .{浮标}
- B29L2031/707: .{线缆,即两个或多个丝状物组合在一起,如绳索,细绳,细线,纱线(丝状材料入B29L2031/731,电缆入B29L2031/3462,光缆入B29L2011/0075)}
- B29L2031/708: .{蜡烛}
- B29L2031/709: .{封闭环状制品,例如输送带}
- B29L2031/711: .{线圈}
- B29L2031/712: .{容器;包装元件或配件,包(瓶塞入B29L31/56;墨水或墨粉盒入B29L2031/7678;挤压管入B29L23/20;手提箱入B29L2031/7418)}
- B29L2031/718: .{美容设备,例如美发,剃刮设备(刷子入B29L31/42,梳子入B29L2021/005)}
- B29L2031/719: .{帘;窗帘;百叶窗}
- B29L2031/72: .{切割设备,如冲床(锯切设备入B29L2031 / 77;研磨设备入B29L2031/736)}
- B29L2031/721: .{减振装置,如减震器(保险杠入B29L2031 / 3044,弹簧入B29L2031/774)}
- B29L2031/722: .{装潢或装饰品 }
- B29L2031/723: .{用于显示或宣传制品(标签,徽章入B29L2031/744)}
- B29L2031/724: .{门}
- B29L2031/725: .{绘图或书写设备}
- B29L2031/726: .{织物(网入B29L28/00)}
- B29L2031/727: .{紧固件(螺栓入B29L2001/002;螺母入B29L2001/005;螺钉入B29L2001/007;拉链入B29L5/00;用于日用小百货的按钮入B29L19/00)}
- B29L2031/73: .{栅栏}
- B29L2031/731: .{丝状材料,即由单一元件例如丝,绳,线,纤维组成(电缆入B29L2031/707)}
- B29L2031/732: .{地板覆盖物(绒毯入B29L2031/7652;用于车辆的入B29L2031/3017)}
- B29L2031/733: .{网带}
- B29L2031/734: .{环状花饰}
- B29L2031/735: .{衣架}
- B29L2031/736: .{研磨或抛光设备}
- B29L2031/737: .{带孔制品,如网格,筛网(网入B29L28/00)}
- B29L2031/738: .{钩}
- B29L2031/739: .{钟表;生产设备}
- B29L2031/74: .{家居用品(餐具入B29L2031/286)}
- B29L2031/7412: .{假奶嘴,安抚奶嘴}
- B29L2031/7414: .{吸烟用品,如清管器(雪茄烟嘴b29l23/14)}
- B29L2031/7418: .{手提箱}
- B29L2031/742: .{小盒子,收纳包,钱包}
- B29L2031/7422: .{雨伞;遮阳伞;登山杖}
- B29L2031/743: .{珠宝}
- B29L2031/744: .{标志,徽章,例如纸套管,}
- B29L2031/745: .{梯子}
- B29L2031/747: .{防雷设备}
- B29L2031/748: .{非另有规定的机器或零件(输送带入B29L2031/7092;传动带入B29L2031/7094;轴承入B29L31/04)}
- B29L2031/751: .{床垫,座垫(内饰入B29L31/58)}
- B29L2031/752: .{测量设备}
- B29L2031/753: .{医疗设备;附件(血袋,医用袋入B29L2031/7148;义眼入B29L2011/0008)}
- B29L2031/755: .{膜,横隔膜}
- B29L2031/756: .{微粒,纳米粒}
- B29L2031/757: .{模具,型芯,压模}
- B29L2031/758: .{音乐设备}
- B29L2031/759: .{针(医用针头入B29L2031/7544)}
- B29L2031/76: .{办公设备或配件}
- B29L2031/762: .{家用电器}
- B29L2031/763: .{降落伞}
- B29L2031/764: .{摄影器材或配件(内存卡入B29L2017/006)}
- B29L2031/765: .{带绒面制品,如毛绒布}
- B29L2031/766: .{电线杆,桅杆,门柱}
- B29L2031/767: .{印刷设备或其附件}
- B29L2031/768: .{防护设备(B29L2031/4821优先)}
- B29L2031/769: .{卫浴设备(尿布入B29L2031/4878)}
- B29L2031/77: .{锯切设备}
- B29L2031/771: .{席位}
- B29L2031/772: .{非另有规定的以形状为特征的制品(封闭环入B29L2031/709;环状入B29L2031/7096;波纹的入B29L16/00,扁平的入B29L7/00;中空的入B29L22/00,螺纹的入B29L1/00;齿形的入B29L2031/775;波纹管入B29L23/18)}
- B29L2031/774: .{弹簧}
- B29L2031/775: .{齿形制品(波纹的入B29L16/00;螺纹的入B29L1/00;波纹管入B29L23/18;梳状的入B29L21/00,齿轮,小齿轮,链轮入B29L15/00)}
- B29L2031/776: .{墙,例如建筑板}
- B29L2031/777: .{武器}
- B29L2031/778: .{窗户(用于制作窗框入B29L2031/005,挡风玻璃入B29L2031/3052)}
- B29L2031/779: .{加热设备}
| 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 | Prosthetic appliance kit | US15210785 | 2016-07-14 | US09868232B2 | 2018-01-16 | Stephen Bettles |
| Prosthetics created in layers, and methods of making them, comprising one or more materials. The methods utilize a clay sculpture from which is made a negative impression cast in silicone, which is used to cast a durable positive prosthetic, which is used to create either durable or temporary negative production impressions into which the layers can be built to form the finished prosthetic. | ||||||
| 122 | Variable Width Deposition for Additive Manufacturing with Orientable Nozzle | US15144957 | 2016-05-03 | US20170320267A1 | 2017-11-09 | Randall F. Lind; Brian K. Post; Lonnie J. Love; Peter D. Lloyd; Charles Lynn Carnal; Craig A. Blue; Vlastimil Kunc |
| An additive manufacturing machine includes a nozzle assembly with a noncircular, rotatable outlet. The nozzle assembly deposits a bead of material having a width that is defined by the angular orientation of the noncircular shaped outlet with respect to the material deposition path direction. The combination of high material deposition rate and fine resolution save time and energy while also producing high-quality parts. | ||||||
| 123 | Dripless liquid color feed throat adaptor and method for dripless liquid color delivery | US14105958 | 2013-12-13 | US09796123B2 | 2017-10-24 | Stephen B. Maguire |
| Apparatus and methods for converting granular plastic resin into colored finished or semi-finished plastic parts include a process machine having a barrel with a vertically opening feed throat, a rotatable screw inside the barrel, and a color feed conduit assembly positioned at least partially within the process machine and extending into the barrel for passage of liquid color downwardly through the color feed conduit assembly into proximity with the screw. | ||||||
| 124 | Powder material for three-dimensional modeling, kit for three-dimensional modeling, device for manufacturing three-dimensional object, and method of manufacturing three-dimensional object | US15065161 | 2016-03-09 | US09782935B2 | 2017-10-10 | Yasuyuki Yamashita; Yasuo Suzuki; Mitsuru Naruse; Nozomu Tamoto; Shigenori Yaguchi; Hitoshi Iwatsuki; Kazumi Ohtaki |
| A powder material for three-dimensional modeling includes a base particle and a coverage film including an organic material. The coverage film covers the base particle. The powder material is used for three dimensional modeling and when the coverage film is dissolved in a solvent to prepare a solution and the solution is formed into a coated film on a smooth surface, the coated film has a wetting tension of from 22 mN/m to 28 mN/m. | ||||||
| 125 | PROCESSING BIOMASS | US15411349 | 2017-01-20 | US20170226549A1 | 2017-08-10 | Marshall Medoff |
| Methods are provided for reducing one or more dimensions of individual pieces of biomass; treating biomass, such as size-reduced biomass; changing a molecular structure of a biomass material; and, optionally, subjecting the biomass to a primary process to form a product. The methods include processing biomass materials using a screw extrusion process, and treating the biomass material with a screw extrusion process in size-reduction and treating steps. | ||||||
| 126 | ADDITIVE MANUFACTURED CONGLOMERATED POWDER REMOVAL FROM INTERNAL PASSAGES WITH CO-BUILT ULTRASONIC HORNS | US15011969 | 2016-02-01 | US20170217094A1 | 2017-08-03 | Caitlin Oswald; Jesse R. Boyer; John P. Rizzo, JR. |
| An additively manufactured component with an internal passage; and a multiple of ultrasonic horns additively manufactured within the internal passage. A method of removing conglomerated powder from an internal passage of an additively manufacturing a component, including ultrasonically exciting at least one of a multiple of the ultrasonic horns within an internal passage of an additively manufactured component | ||||||
| 127 | Method and apparatus for dry granulation | US14582664 | 2014-12-24 | US09700513B2 | 2017-07-11 | Giovanni Politi; Erkki Heilakka |
| The invention provides, inter alia, a method for producing granules from a powder, characterized in that compaction force is applied to the powder to produce a compacted mass comprising a mixture of fine particles and granules and separating and removing fine particles and/or small granules from the other granules by entraining the fine particles and/or small granules in a gas stream. Also provided are apparatus for use in the process and tablets formed by compression of the resultant granules. | ||||||
| 128 | Batch mixer with plunger | US14789106 | 2015-07-01 | US09643352B2 | 2017-05-09 | Fares D. Alsewailem |
| A batch mixer is equipped with a plunger for pushing material from the batch mixer. The batch mixer includes a mixer tank structured to accommodate material. The mixer further includes a mixer head comprising at least one blade structured to blend the material within the mixer tank. The mixer further includes a plunger mechanism structured to push the blended material directly from the mixer tank. | ||||||
| 129 | METHOD AND SYSTEM FOR PERFORMING AN INFRARED TREATMENT | US15297737 | 2016-10-19 | US20170100856A1 | 2017-04-13 | Aarne Heino; Ilya Kaufman |
| A method for performing an infrared treatment includes the steps of receiving an extruded product and feeding the extruded product to an oven including at least one lamp unit. The lamp unit includes a lamp, a reflective surface enclosing a first side of the lamp and positioned to direct radiation from the lamp, and a glass disposed between a second side of the lamp and an extruded product, wherein the glass separates the lamp and the extruded product. The method further includes the step of creating cross-linking between layers of the extruded product by directing the radiation at the extruded product. Still further, the method includes the steps of directing a first gas flow at a surface of the product and directing a second gas flow at the glass. | ||||||
| 130 | METHOD FOR A COMPOSITE MATERIAL IMPREGNATED WITH THERMOPLASTIC POLYMER, OBTAINED FROM A PREPOLYMER AND A CHAIN EXTENDER | US15304657 | 2015-04-15 | US20170037208A1 | 2017-02-09 | Gilles Hochstetter; Thierry Briffaud; Mathieu Capelot |
| A process for a composite material, including an assembly of one or more reinforcing fibers, impregnated with at least one thermoplastic polymer with a glass transition temperature Tg of less than or equal to 75° C. and a melting point of from 150° C. to less than 250° C. or a Tg of greater than 75° C., the process including: i) a step of impregnating said assembly in bulk melt form with at least one thermoplastic polymer, which is the product of polymerization by polyaddition reaction of a reactive precursor composition including: a) at least one prepolymer P(X)n of said thermoplastic polymer, and b) at least one chain extender, represented by Y-A-Y, ii) a step of cooling and obtaining a fibrous preimpregnate, and iii) a step of processing and final forming of said composite material. | ||||||
| 131 | UNIFORMITY OF FIBER SPACING IN CMC MATERIALS | US14813239 | 2015-07-30 | US20170029340A1 | 2017-02-02 | Jared Hogg WEAVER; Gregory Scot CORMAN; Daniel Gene DUNN |
| A pre-impregnated composite tape is provided that includes: a matrix material; a plurality of fibers forming unidirectional arrays of tows encased within the matrix material; and a plurality of filler particles dispersed between adjacent fibers in the tape. The fibers have a mean fiber diameter of about 5 microns and about 40 microns, and are included within the tape at a volume fraction of about 15% and about 40%. The plurality of filler particles have a log-normal volumetric median particle size, such that the tape has a ratio of the log-normal volumetric median particle size to the mean fiber diameter that is about 0.05:1 to about 1:1. A method is also provided for forming a ceramic matrix composite. | ||||||
| 132 | SYSTEMS AND METHODS FOR ADDITIVELY MANUFACTURING COMPOSITE PARTS | US15063347 | 2016-03-07 | US20170028637A1 | 2017-02-02 | Nick S. Evans; Faraón Torres; Ryan G. Ziegler; Samuel F. Harrison; Ciro J. Grijalva, III; Hayden S. Osborn |
| A system (700) for additively manufacturing a composite part (102) comprises a delivery guide (112), movable relative to a surface (114). The delivery guide (112) is configured to deposit at least a segment (120) of a continuous flexible line (106) along a print path (122). The continuous flexible line (106) comprises a non-resin component (108) and a thermosetting-resin component (110). The thermosetting-resin component (110) comprises a first part (253) and a second part (255). The non-resin component (108) comprises a first element (271) and a second element (273). The system (700) further comprises a first resin-part applicator (236), configured to apply the first part (253) to the first element (271), and a second resin-part applicator (237), configured to apply the second part (255) to the second element (273). The system (700) also comprises a feed mechanism (104), configured to pull the first element (271) through the first resin-part applicator (236), to pull the second element (273) through the second resin-part applicator (237), and to push the continuous flexible line (106) out of the delivery guide (112). | ||||||
| 133 | SYSTEMS AND METHODS FOR ADDITIVELY MANUFACTURING COMPOSITE PARTS | US14995742 | 2016-01-14 | US20170028625A1 | 2017-02-02 | Nick S. Evans; Faraón Torres; Ryan G. Ziegler; Samuel F. Harrison; Ciro J. Grijalva, III; Hayden S. Osborn |
| A method (400) of additively manufacturing a composite part (102) is disclosed. The method (400) comprises applying a thermosetting resin (252) to a non-resin component (108) of a continuous flexible line (106) while pushing the non-resin component (108) through a delivery guide (112) and pushing the continuous flexible line (106) out of the delivery guide (112). The continuous flexible line (106) further comprises a thermosetting resin component (110) that comprises at least some of the thermosetting resin (252) applied to the non-resin component (108). The method (400) further comprises depositing, via the delivery guide (112), a segment (120) of the continuous flexible line (106) along the print path (122). | ||||||
| 134 | SYSTEMS AND METHODS FOR ADDITIVELY MANUFACTURING COMPOSITE PARTS | US14931692 | 2015-11-03 | US20170028621A1 | 2017-02-02 | Nick S. Evans; Faraón Torres; Ryan G. Ziegler; Samuel F. Harrison; Ciro J. Grijalva, III; Hayden S. Osborn |
| A method (400) of additively manufacturing a composite part (102) is disclosed. The method (400) comprises depositing, via a delivery guide (112), a segment (120) of a continuous flexible line (106) along a print path (122). The continuous flexible line (106) comprises a non-resin component (108) and a thermosetting-epoxy-resin component (110) that is partially cured. The method (400) also comprises maintaining the thermosetting-epoxy-resin component (110) of at least the continuous flexible line (106) being advanced toward the print path (122) via the delivery guide (112) below a threshold temperature. The method (400) further comprises delivering a predetermined or actively determined amount of curing energy (118) to the segment (120) of the continuous flexible line (106) at a controlled rate while advancing the continuous flexible line (106) toward the print path (122) to at least partially cure the segment (120) of the continuous flexible line (106). | ||||||
| 135 | SYSTEMS AND METHODS FOR ADDITIVELY MANUFACTURING COMPOSITE PARTS | US14841500 | 2015-08-31 | US20170028620A1 | 2017-02-02 | Nick S. Evans; Faraón Torres; Ryan G. Ziegler; Samuel F. Harrison; Ciro J. Grijalva, III; Hayden S. Osborn |
| A method (400) of additively manufacturing a composite part (102) comprises pushing a continuous flexible line (106) through a delivery guide (112). The continuous flexible line comprises (106) a non-resin component (108) and a photopolymer-resin component (110) that is partially cured. The method (400) also comprises depositing, via the delivery guide (112), a segment (120) of the continuous flexible line (106) along a print path (122). Additionally, the method (400) comprises delivering curing energy (118) at least to a portion (124) of the segment (120) of the continuous flexible line (106) deposited along the print path (122). | ||||||
| 136 | SYSTEMS AND METHODS FOR ADDITIVELY MANUFACTURING COMPOSITE PARTS | US14920767 | 2015-10-22 | US20170028617A1 | 2017-02-02 | Nick S. Evans; Faraón Torres; Ryan G. Ziegler; Samuel F. Harrison; Ciro J. Grijalva, III; Hayden S. Osborn |
| A method (300) of additively manufacturing composite part (102) comprises depositing a segment (120) of a continuous flexible line (106) along a print path (122). The continuous flexible line (106) comprises a non-resin component (108) and further comprises a photopolymer-resin component (110) that is uncured. The method (300) further comprises delivering a predetermined or actively determined amount of curing energy (118) at least to a portion (124) of the segment (120) of the continuous flexible line (106) at a controlled rate while advancing the continuous flexible line (106) toward the print path (122) and after the segment (120) of the continuous flexible line (106) is deposited along the print path (120) to at least partially cure at least the portion (124) of the segment (120) of the continuous flexible line (106). | ||||||
| 137 | Flexible fabric having superhydrophobic surface | US14221059 | 2014-03-20 | US09556554B2 | 2017-01-31 | Alan Michael Lyons; QianFeng Xu |
| The disclosure relates to a superhydrophobic surface. Methods of fabrication are disclosed including laminating an optically transparent polymer sheet with hydrophobic nanoparticles such that the nanoparticles are partially embedded and partially exposed. The resulting assembly remains optically transparent. Additional methods include the lamination of nanoparticles to flexible fabrics and the production of molded articles using nanoparticle-treated molds. | ||||||
| 138 | SYSTEMS AND METHODS FOR INCREMENTALLY FORMING A COMPOSITE PART | US14808989 | 2015-07-24 | US20170021534A1 | 2017-01-26 | Michael Robert Chapman; Charles M. Richards; Jeffrey M. Hansen; Robert L. Anderson |
| Systems and methods for incrementally forming a composite part are disclosed herein. The systems include a forming mandrel, which includes a forming surface, and a forming machine. The forming machine includes a forming bladder, a pressure-regulating device, and a positioning device. The forming bladder is configured to be inflated to a forming pressure and to press the ply of composite material against the forming surface. The methods include placing a ply of composite material on a forming surface of a forming mandrel and pressing a forming bladder against the ply of composite material at a selected location to press a selected portion of the ply of composite material against the forming surface and conform the selected portion of the ply of composite material to a surface profile of the forming surface. The methods further include repeating the pressing a plurality of times at a plurality of selected locations. | ||||||
| 139 | Mold for casting concrete | US14804353 | 2015-07-21 | US20170021533A1 | 2017-01-26 | Jian Qing WANG |
| A mold for casting concrete contains: an inner part, an outer par, a temperature insulation layer, a fixing plate, and a pulling member. The inner part includes a cavity, an inlet, and an outlet which communicate with one another to flow first fluid into the cavity from the inlet and to discharge the first fluid out of the outlet from the cavity. The inner part further includes an outer fence and an inner fence on which the temperature insulation layer is arranged. The outer part is located outside the outer fence, between the outer part and the outer fence is defined a feeding chamber. The outer part includes a heating element and second fluid both defined therein, and the heating element is immersed in the second fluid. The fixing plate is mounted on the outer part and the inner part. The pulling member is fixed on the inner part. | ||||||
| 140 | METHOD FOR PRODUCING PLASTIC COMPONENTS, WHICH HAVE A HIGH MECHANICAL LOAD-BEARING CAPACITY, WITH A CORRECT FINAL CONTOUR | US14901935 | 2014-07-25 | US20160368187A1 | 2016-12-22 | MARTIN SCHNEEBAUER; MARTIN WUERTELE |
| A method for producing plastic components, which have a high mechanical load-bearing capacity, with a correct final contour is disclosed. In the method an injection casting process is carried out in a first step using a thermoplastic molding compound in a closed tool consisting of a female die and a male die, a thermoplastic molding compound with a high viscosity being used in order to provide a sufficient seal of the tool or the cavity at the tool parting plane between the female die and the male die in comparison to a molding compound with an extremely low viscosity used in a second step. The cavity is increased prior to the second step such that the seal formed by the molding compound is fixed on or in the molding compound with the extremely low viscosity after said molding compound is injected and cured to such an extent that the molding compounds forms a composite component. | ||||||
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