81 |
METHOD OF MANUFACTURING A DRAWN MULTIFILAMENT YARN |
EP14701413.8 |
2014-01-27 |
EP2948579B1 |
2016-11-09 |
DANSCHUTTER, DE, Evert Florentinus Florimondus; MITTENZWEI, Andreas Oliver |
|
82 |
A YARN COMPRISING GEL-FORMING FILAMENTS OR FIBRES |
EP12798352.6 |
2012-11-29 |
EP2785901A1 |
2014-10-08 |
BONNEFIN, Wayne; WROE, Sarah; PRENTICE, Amelia |
A wound dressing for use in vacuum wound therapy comprising a wound contact layer which is an open structure comprising a yarn comprising gel-forming filaments or fibres, the structure having a porosity which allows exudate to flow through it. |
83 |
ORGANIC MATERIAL REMOVING DEVICE |
US15742352 |
2016-03-08 |
US20180370077A1 |
2018-12-27 |
Keiichi KASUGA; Shinichi KAWASUMI; Kazuhito KOBAYASHI |
An organic material removing device includes: a container for storing a composite material containing an inorganic material and an organic material decomposable by a treatment liquid; a treatment tank including an accommodation portion for accommodating the container, a treatment liquid inflow portion for allowing the treatment liquid to flow in, and a treatment liquid outflow portion for allowing the treatment liquid to flow out; temperature control means for heating or cooling the treatment liquid; and a treatment liquid circulation means for allowing the treatment liquid to flow in from the treatment liquid inflow portion into the treatment tank and allowing the treatment liquid in the treatment tank to flow out from the treatment liquid outflow portion. |
84 |
Production method of superclean wiper |
US14758182 |
2013-09-02 |
US10106920B2 |
2018-10-23 |
Jun Zhang |
Disclosed is a production method of superclean wiping cloth, including the steps of choosing filament, weaving, removing oligomers and dust particles through rinsing process, dehydrating, setting, cutting, washing, drying, and packaging; wherein removing oligomers and dust particles through rinsing process is the key process, the airflow rinsing machine is used to rinse the gray fabric, avoiding the reverse contamination and cloth damage during washing, ensuring a high cleanliness of the gray fabric. Excellent effect of removing oligomers and dust particles will be achieved through adding degreasers of specific formula, in a clean environment, at a specific temperature, whereby a wiping cloth product with stable quality, i.e., real superclean wiping cloth, will be obtained. The rising process is simple and highly efficient, it ensures the stability of product quality and high cleanliness, producing a superclean wiping cloth with high cleanliness and stable quality, using a simple and efficient production process. |
85 |
System for injecting functional solution for fabric and method for manufacturing fabric using same |
US14997420 |
2016-01-15 |
US09951450B2 |
2018-04-24 |
Young chul Joung; Myung je Roh; Jong chul Park; Min woo Kim; Mun hyeong Lee; In chang Cha |
The present invention relates to a system for injecting a functional solution for fabric and a method for manufacturing fabric using same. The system includes: a first supply portion; a second supply portion provided with a distributing device; an injection portion provided with a needle; a drying portion provided with a hot air blower or a blower; and a collection portion provided with a collecting roll. An injection method is provided in which the needle on the injection portion, installed so as to be moved reciprocally, is directly inserted into the fabric to inject the functional solution, so that the functional solution is absorbed from the outer surface to the inside of the fabric. |
86 |
PRODUCTION METHOD OF SUPERCLEAN WIPING CLOTH |
US14758182 |
2013-09-02 |
US20160194789A1 |
2016-07-07 |
Jun Zhang |
Disclosed is a production method of superclean wiping cloth, including the steps of choosing filament, weaving, removing oligomers and dust particles through rinsing process, dehydrating, setting, cutting, washing, drying, and packaging; wherein removing oligomers and dust particles through rinsing process is the key process, the airflow rinsing machine is used to rinse the gray fabric, avoiding the reverse contamination and cloth damage during washing, ensuring a high cleanliness of the gray fabric. Excellent effect of removing oligomers and dust particles will be achieved through adding degreasers of specific formula, in a clean environment, at a specific temperature, whereby a wiping cloth product with stable quality, i.e., real superclean wiping cloth, will be obtained. The rising process is simple and highly efficient, it ensures the stability of product quality and high cleanliness, producing a superclean wiping cloth with high cleanliness and stable quality, using a simple and efficient production process. |
87 |
SYSTEM FOR INJECTING FUNCTIONAL SOLUTION FOR FABRIC AND METHOD FOR MANUFACTURING FABRIC USING SAME |
US14997420 |
2016-01-15 |
US20160130736A1 |
2016-05-12 |
Young chul JOUNG; Myung je ROH; Jong chul PARK; Min woo KIM; Mun hyeong LEE; In chang CHA |
The present invention relates to a system for injecting a functional solution for fabric and a method for manufacturing fabric using same. The system includes: a first supply portion; a second supply portion provided with a distributing device; an injection portion provided with a needle; a drying portion provided with a hot air blower or a blower; and a collection portion provided with a collecting roll. An injection method is provided in which the needle on the injection portion, installed so as to be moved reciprocally, is directly inserted into the fabric to inject the functional solution, so that the functional solution is absorbed from the outer surface to the inside of the fabric. |
88 |
Polyester Fiber and Lightweight Woven Nylon Yarn Blended Process |
US14084914 |
2013-11-20 |
US20140366346A1 |
2014-12-18 |
PEI-YUAN LEE; CHUN-LIANG KUO |
A polyester fiber and lightweight woven nylon yarn blended process may include a lightweight weaving procedure, a secondary lightweight procedure, a dyeing procedure; and a water rinsing and drying procedure. In one embodiment, in the lightweight weaving procedure, a plurality of chemical monofilament fibers is twirled into bunched chemical monofilament fibers by a kneading process, the bunched chemical monofilament fibers and a woven complex yarn (polyester fiber and woven nylon yarn) are fed into a loom simultaneously, the loom is equipped with a fiber opening knife for performing a fiber opening process for the woven complex yarn, the fiber opening knife performs the fiber opening process to cut the woven complex yarn into a plurality of equal sized furcal structures longitudinally to cause wear and tear to achieve lightweight preliminarily, then the furcal structures and the bunched chemical monofilament fibers are undergone a knitting process to obtain a lightweight fabric; |
89 |
WOUND DRESSING FOR USE IN VACUUM THERAPY |
US14362039 |
2012-11-29 |
US20140323999A1 |
2014-10-30 |
Wayne Bonnefin; Sarah Wroe; Amelia Prentice |
A wound dressing for use in vacuum wound therapy comprising a wound contact layer which is an open structure comprising a yarn comprising gel-forming filaments or fibres, the structure having a porosity which allows exudate to flow through it. |
90 |
Drum coagulator for preparing microporous membranes |
US465768 |
1983-02-11 |
US4598662A |
1986-07-08 |
William K. W. Chen |
A process and device for producing a flexible layered article suitable for use in water proof garments wherein one of said layers is a microporous membrane material produced from the "solvent non-solvent" method wherein a fabric backing coated with the membrane material dissolved in a solvent is contacted with a drum having gripping means offering substantial resistance to the natural tendency of the coated fabric to curl when immersed in a non-solvent for the polymer material. |
91 |
Methods of dyeing fabric with a hydrocarbon subsequently burned |
US33431073 |
1973-02-21 |
US3904360A |
1975-09-09 |
SCHUIERER MANFRED |
Dyeing or otherwise chemically finishing a textile fabric by applying to the fabric a mixture of the finishing chemical and at least one organic solvent which is vaporised following its application to the fabric and burned. The solvent is one which, upon oxidation, is converted to carbon dioxide and water.
|
92 |
Process and apparatus for the controlled treatment of textiles |
US3473175D |
1968-02-14 |
US3473175A |
1969-10-21 |
SIEBER JOHANNES HELMUT |
|
93 |
Degreasing of strip material by solvent vapour |
US43680665 |
1965-03-03 |
US3350734A |
1967-11-07 |
ANDERS HOLM KURT |
|
94 |
Manufacture of coated material |
US77463058 |
1958-11-18 |
US3136654A |
1964-06-09 |
CRAVER AUGUSTUS E |
|
95 |
Desizing process |
US68301757 |
1957-09-10 |
US3019140A |
1962-01-30 |
WILLIAM KILBY; STEPHEN WHITE WILFRED ARTHUR |
|
96 |
Method of impregnating fibrous webs with a novolac resin |
US36296553 |
1953-06-19 |
US2808350A |
1957-10-01 |
SEILER CHARLES J |
|
97 |
PROOFING DYEING CUP FOR SUPERCRITICAL FLUID DYEING AND FINISHING |
US15556699 |
2016-06-06 |
US20180187355A1 |
2018-07-05 |
Jiajie LONG; Jianzhong GUO |
The invention discloses a proofing dyeing cup for supercritical fluid waterless dyeing and finishing, which achieves separate or simultaneous filling of the medium into multiple dyeing units, and simultaneous heating of the dyeing units for proofing processing. Efficiency of proofing processing such as high-pressure supercritical fluid waterless dyeing and thus the utilization rate of the medium boosting and filling system and separation and recycling system are significantly improved, so that the proofing requirements of commercial production of textile waterless dyeing and finishing are met. Furthermore, dye chemicals at the bottom of the cup can be stirred to facilitate dissolution, and the dye chemicals at the bottom of the cup can be swept and cleaned. Thus, defects of an existing fixed supercritical fluid dyeing proofing device or an equipment system thereof, such as low utilization efficiency, complex cleaning and incapability of meeting the proofing requirements of commercial production, are overcome. |
98 |
Method for making three dimension preform having high heat conductivity and method for making aircraft brake disc having the three dimension preform |
US14580763 |
2014-12-23 |
US09689446B2 |
2017-06-27 |
Chae Wook Cho; Jong Hyun Park; Min Cheol Cho; Kap Su Jung; Gi Bum Ryu |
A method of manufacturing a three dimension preform having high thermal conductivity includes: a first step of manufacturing a unidirectional carbon fabric from a heat resistant fiber; a second step of putting the unidirectional carbon fabric into an aqueous solution with carbon nanomaterials contained in a vessel; a third step of taking the unidirectional carbon fabric out of the vessel and then drying the unidirectional carbon fabric; a fourth step of repeating the second step and the third step; a fifth step of stacking the unidirectional carbon fabrics with web carbon fabrics, which are made of a heat resistant fiber, inserted between the unidirectional carbon fabrics; and a sixth step of punching the stacked unidirectional carbon fabrics and the web carbon fabrics with a needle. |
99 |
Yarn comprising gel-forming filaments or fibres |
US14362050 |
2012-11-29 |
US09562305B2 |
2017-02-07 |
Wayne Bonnefin; Sarah Wroe; Amelia Prentice |
A yarn comprising gel forming filaments or fibers particularly one used to make a woven or knitted wound dressing or other gelling fabric structure. The invention provides a yarn comprising a blend of from 30% to 100% by weight of gel-forming fibers and 0% to 70% by weight of textile fibers. Process for making the yarns are also described including those using rotor spinning. |
100 |
METHOD FOR MAKING THREE DIMENSION PREFORM HAVING HIGH HEAT CONDUCTIVITY AND METHOD FOR MAKING AIRCRAFT BRAKE DISC HAVING THE THREE DIMENSION PREFORM |
US14580763 |
2014-12-23 |
US20150240891A1 |
2015-08-27 |
Chae Wook CHO; Jong Hyun PARK; Min Cheol CHO; Kap Su JUNG; Gi Bum RYU |
A method of manufacturing a three dimension preform having high thermal conductivity includes: a first step of manufacturing a unidirectional carbon fabric from a heat resistant fiber; a second step of putting the unidirectional carbon fabric into an aqueous solution with carbon nanomaterials contained in a vessel; a third step of taking the unidirectional carbon fabric out of the vessel and then drying the unidirectional carbon fabric; a fourth step of repeating the second step and the third step; a fifth step of stacking the unidirectional carbon fabrics with web carbon fabrics, which are made of a heat resistant fiber, inserted between the unidirectional carbon fabrics; and a sixth step of punching the stacked unidirectional carbon fabrics and the web carbon fabrics with a needle. |