61 |
近接近の間接暴露を利用する、ポリマー材料の大気圧プラズマ処理 |
JP2015543102 |
2013-11-19 |
JP2016504713A |
2016-02-12 |
フェリックス・エー・パウラウスカス; トルーマン・エー・ボンズ |
中間の加熱容積および内部の処理容積を含む処理チャンバを用意するステップを含むプラズマ処理方法。内部の処理容積はプラズマを発生するための電極組立体を含有し、中間の加熱容積が内部の処理容積を加熱する。被加工物は処理チャンバを通り抜ける。処理チャンバの内部の処理容積に処理ガスが導入される。電極組立体を用いて処理ガスからプラズマが形成され、プラズマの反応種は、電極組立体が内部の処理容積に生成した流れ渦によって繊維トウの方へ加速される。 |
62 |
Apparatus for activating ionizable substance |
JP2003120838 |
2003-04-25 |
JP2004321951A |
2004-11-18 |
IWATA TAKUZO |
PROBLEM TO BE SOLVED: To provide an apparatus for activating an ionizable substance in which the whole of the ionizable substance can be efficiently activated at a time by increasing the penetration of a plasma particle into the ionizable substance.
SOLUTION: This apparatus 1 for activating the ionizable substance is provided with a magnetic field generating unit 2 for generating a magnetic field and a corona discharge unit 3 for releasing the plasma particle E by corona discharge toward the ionizable substance M placed on the unit 2. The unit 2 is arranged so that the north pole side of the unit 2 is faced to the side of the corona discharge unit 3.
COPYRIGHT: (C)2005,JPO&NCIPI |
63 |
By harmful gas or gas mixture, the plant that contains the reactor and the it for a solid material processing |
JP2001572211 |
2001-03-28 |
JP2003528722A |
2003-09-30 |
ルカ シュワスナール; ベルナール ルマン |
(57)【要約】 本発明は、逆流及び複数の効果という原理によって作動するリアクタに関する。 それは、好ましくは、ガスの送入手段と、処理により得られたガスの排出手段と、被処理材料の受入手段と、処理済み材料の取出手段と、導入部と取出部との間において材料を搬送する手段とを備え、ガスの送入手段及び処理済み材料の取出手段は、ガスが処理済み材料用出口からリアクタ内に送入されるように設計され配置され、処理の結果得られたガスの排出手段及び被処理材料の受入手段は、処理の結果得られるガス混合物が被処理材料用取入口に残存するように設計され配置される。 図2は、複数の効果が生じる密閉セル(2)を備えた反応チャンバー(1)を示す。 |
64 |
Flame retardant processing method of cellulose fabrics |
JP20193191 |
1991-08-12 |
JP2963559B2 |
1999-10-18 |
ROBAATO KOORU |
|
65 |
Apparatus for flame-retardant treatment of cellulose textile |
JP20193191 |
1991-08-12 |
JPH04245968A |
1992-09-02 |
ROBAATO KOORU |
PURPOSE: To efficiently carry out a flame-retardant treatment by introducing a cellulose-based woven fabric impregnated with a specific phosphorus-containing organic compound to a chamber sealed in an airtight state and treating the fabric with an ammonia-containing gas. CONSTITUTION: A cellulose-based woven fabric impregnated with a tetrakis(hydroxyorgano)phosphonium composition is introduced into a chamber equipped with an inclined roof 5 and an inlet 2 and an outlet 13 to be sealed in an airtight state. The woven fabric is brought into contact with a dust 3 at <60 degree contact angles while being traveled in a meandered state through plural rollers 4 installed in the chamber 1 an ammonia-containing gas is fed from an orifice of the duct 3 and the woven fabric is treated at a fixed temperature while recycling the gas. The woven fabric is withdrawn from the outlet 13, oxidized, neutralized/washed/dried. The cellulose-based woven fabric comprises <30 wt.% of cellulose fiber and <70 wt.% of polyester fiber. The gas contains ammonia of 70-90% initial concentration. |
66 |
JPH0377303B2 - |
JP22343083 |
1983-11-29 |
JPH0377303B2 |
1991-12-10 |
JAN PIEERU TSUMUBURUN; JAN RUIERU; ANDORE TOOMA; FURANSOWA GURANJUTO |
|
67 |
Continuous alkali weight reducing apparatus |
JP10049981 |
1981-06-30 |
JPS584866A |
1983-01-12 |
ARASHI MASAKIMI |
|
68 |
Method and apparatus for improving quality and feeling of fabric or knitted fabric |
JP2831279 |
1979-03-13 |
JPS54142395A |
1979-11-06 |
DEIITERU RIIDERU; BUENTSUERU BURENIKU |
|
69 |
Method and apparatus for removing ammonia in liquid ammonia treatment of fabric |
JP2716178 |
1978-03-08 |
JPS5488373A |
1979-07-13 |
JIYAKUSON ROORENSU; HARII EE UEBU |
|
70 |
Ammonia treatment of cloth |
JP13583076 |
1976-11-10 |
JPS52152595A |
1977-12-19 |
JIYAKUSON ROORENSU |
|
71 |
Senizairyonosenshokuhoho |
JP6711575 |
1975-06-05 |
JPS514378A |
1976-01-14 |
JAN HOORU DARU; MARIBONNU UAESUKAN |
|
72 |
JPS5043279A - |
JP8596174 |
1974-07-26 |
JPS5043279A |
1975-04-18 |
|
|
73 |
Rubbing alignment equipment |
US15098496 |
2016-04-14 |
US10139682B2 |
2018-11-27 |
Chengyong Zhan; Kai Wang; Cong Tan; Bo Zhang; Liangliang Jiang |
The invention provides a rubbing alignment equipment, which belongs to the field of rubbing alignment technology and can solve the problem of badness of an alignment film during rubbing alignment due to the badness of the existing rubbing cloth. The rubbing alignment equipment of the invention comprises a rubbing roller, which comprises a roll shaft and rubbing cloth wound on the outer surface of the roll shaft, the rubbing cloth is doped with quantum dots, the rubbing alignment equipment further comprises an excitation light source, which can excite the quantum dots to emit light to detect whether the surface of the rubbing cloth has badness or not. The rubbing alignment equipment can well detect whether the rubbing cloth has badness or not. |
74 |
Atmospheric pressure plasma processing of polymeric materials utilizing close proximity indirect exposure |
US15239101 |
2016-08-17 |
US10138305B2 |
2018-11-27 |
Felix L. Paulauskas; Truman Bonds |
A plasma treatment method that includes providing treatment chamber including an intermediate heating volume and an interior treatment volume. The interior treatment volume contains an electrode assembly for generating a plasma and the intermediate heating volume heats the interior treatment volume. A work piece is traversed through the treatment chamber. A process gas is introduced to the interior treatment volume of the treatment chamber. A plasma is formed with the electrode assembly from the process gas, wherein a reactive species of the plasma is accelerated towards the fiber tow by flow vortices produced in the interior treatment volume by the electrode assembly. |
75 |
METHODS AND APPARATUSES FOR PROCESSING TEXTILE FIBERS, KETTLE AUTOMATIC OPERATION DEVICES, AND TEXTILE FIBER PRODUCTS |
US15870927 |
2018-01-13 |
US20180282944A1 |
2018-10-04 |
Xiaohua Huang |
A method for processing textile fibers is provided. The method comprises: adding a plurality of raw materials for processing textile fibers into a plurality of kettles; preparing supercritical carbon dioxide; obtaining one or more natural plant dyes and one or more natural plant extracts from the plurality of raw materials, and dissolving the one or more natural plant dyes and the one or more natural plant extracts in the supercritical carbon dioxide; dyeing and functionally modifying the textile fibers simultaneously by using the supercritical carbon dioxide carrying a mixture of the one or more natural plant dyes and the one or more natural plant extracts; performing a post-process to recycle the supercritical carbon dioxide; and performing a cleaning process to clean the one or more natural plant dyes and one or more natural plant extracts. |
76 |
MOBILE DYEING CUP FOR SUPERCRITICAL FLUID DYEING AND FINISHING |
US15556681 |
2016-06-06 |
US20180094374A1 |
2018-04-05 |
Jiajie LONG; Jianzhong GUO |
The invention discloses a mobile dyeing cup for supercritical fluid waterless dyeing and finishing. The dyeing cup achieves separate or simultaneous filling of the medium into multiple dyeing units, and simultaneous heating of the dyeing units for proofing processing. A medium outlet is provided at the lowest position of the bottom of the cup, and the inner surface of the dyeing cup is coated with polytetrafluoroethylene, to effectively reduce residual dye chemicals in the cup and improve the cleaning efficiency. The perforated baffle at the bottom of the cup effectively prevents a textile product from blocking the medium outlet during medium filling and outputting, so that the processing medium and residual dye chemicals can be smoothly discharged. Accordingly, defects of an existing fixed proofing device such as low utilization efficiency, complex cleaning and incapability of meeting the proofing requirements of commercial production are overcome. |
77 |
SYSTEM AND METHOD FOR SURFACE TREATMENT AND BARRIER COATING OF FIBERS FOR IN SITU CNT GROWTH |
US14174715 |
2014-02-06 |
US20170240425A9 |
2017-08-24 |
Harry C. MALECKI; Mark R. Alberding; Brandon K. Malet; Tushar K. Shah |
A system for synthesizing carbon nanotubes (CNT) on a fiber material includes a surface treatment system adapted to modify the surface of the fiber material to receive a barrier coating upon which carbon nanotubes are to be grown, a barrier coating application system downstream of the surface treatment system adapted to apply the barrier coating to the treated fiber material surface, and a barrier coating curing system downstream of the barrier coating application systems for partially curing the applied barrier coating to enhance reception of CNT growth catalyst nanoparticles. |
78 |
ATMOSPHERIC PRESSURE PLASMA PROCESSING OF POLYMERIC MATERIALS UTILIZING CLOSE PROXIMITY INDIRECT EXPOSURE |
US15239101 |
2016-08-17 |
US20160355614A1 |
2016-12-08 |
Felix L. Paulauskas; Truman Bonds |
A plasma treatment method that includes providing treatment chamber including an intermediate heating volume and an interior treatment volume. The interior treatment volume contains an electrode assembly for generating a plasma and the intermediate heating volume heats the interior treatment volume. A work piece is traversed through the treatment chamber. A process gas is introduced to the interior treatment volume of the treatment chamber. A plasma is formed with the electrode assembly from the process gas, wherein a reactive species of the plasma is accelerated towards the fiber tow by flow vortices produced in the interior treatment volume by the electrode assembly. |
79 |
SUPERCRITICAL FLUID ROLLED OR SPOOLED MATERIAL FINISHING |
US15048639 |
2016-02-19 |
US20160244912A1 |
2016-08-25 |
Matt W. Kelly |
Methods are directed to the use of a supercritical fluid for performing a dyeing of a material such that dye from a first material is used to dye a second material. A supercritical fluid is passed through a first material in a pressurized vessel. The supercritical fluid transports the dye from the first material to at least a second material causing a dye profile of the second material to change as a result of dye from the first material perfusing the second material. |
80 |
PLASMA PROCESSING APPARATUS |
US14917052 |
2014-07-09 |
US20160194817A1 |
2016-07-07 |
Songying MO; Qiming ZHENG; Wui Yin HO |
A plasma processing apparatus, comprising at least one sealed chamber (2), a vacuum device and working gas feed device in communication with the sealed chamber (2), and a plasma processing device and a garment support mechanism (5) arranged inside the sealed chamber (2); the plasma processing device comprises at least two parallel spaced electrode plates (41), and the garment support mechanism (5) comprises a support frame (51) provided between every two adjacent electrode plates (41) and used for supporting at least one garment (1) and fully opening the garment (1). The present plasma processing apparatus simultaneously plasma processes a plurality of garments (1) on a plurality of support frames (51); according to requirements, the necessary working gas is fed and imparts the garments (1) with different properties; the apparatus allows processing to be done in bulk, improves plasma garment processing speed, and is suitable for use in industrial processing. |