2017 Patent of Textile Science and Engineering of Wuhan Textile University
Number |
Heading |
Application Number |
Date |
Applicant (patent) |
Inventor |
Main classification number |
Classification number |
1 |
Printing, dyeing and stirring device |
201720485743.1 |
2017.05.03 |
Yantai Industry YeLin Textile Printing & Dyeing Co., Ltd. Wuhan Textile University |
Jinlong Wei ; YuJun Wang ; Jinbo Yao ; Yu willJiang; Zangjin Ting |
B01F7/18(2006.01) |
B01F7/18(2006.01);B01F5/10(2006.01);B01F15/00(2006.01) |
2 |
Printing and dyeing equipment |
201720485731.9 |
2017.05.03 |
Yantai Industry YeLin Textile Printing & Dyeing Co., Ltd. Wuhan Textile University |
Jinlong Wei ; YuJun Wang ; Jinbo Yao ; Yu willJiang; Zangjin Ting |
D06B1/00(2006.01) |
D06B1/00(2006.01);D06B23/20(2006.01);D06B23/00(2006.01) |
3 |
Tension setting feeding mechanism |
201720482246.6 |
2017.05.03 |
Yantai Industry YeLin Textile Printing & Dyeing Co., Ltd. Wuhan Textile University |
Jinlong Wei ; YuJun Wang ; Jinbo Yao ; Yu willJiang; Zangjin Ting |
D06C7/02(2006.01) |
D06C7/02(2006.01);D06C3/00(2006.01) |
4 |
Embossing machine receiving device |
201720482242.8 |
2017.05.03 |
Yantai Industry YeLin Textile Printing & Dyeing Co., Ltd. Wuhan Textile University |
Jinlong Wei ; YuJun Wang ; Jinbo Yao ; Yu willJiang; Zangjin Ting |
D06C23/04(2006.01) |
D06C23/04(2006.01) |
5 |
Calender extrusion device for composite fabric |
201720481835.2 |
2017.05.03 |
Yantai Industry YeLin Textile Printing & Dyeing Co., Ltd. Wuhan Textile University |
Jinlong Wei ; YuJun Wang ; Jinbo Yao ; Yu willJiang; Zangjin Ting |
D06N3/00(2006.01) |
D06N3/00(2006.01) |
6 |
Jitter dusting and grinding machine |
201720481434.7 |
2017.05.03 |
Yantai Industry YeLin Textile Printing & Dyeing Co., Ltd. Wuhan Textile University |
Jinlong Wei ; YuJun Wang ; Jinbo Yao ; Yu willJiang; Zangjin Ting |
D06C11/00(2006.01) |
D06C11/00(2006.01) |
7 |
Gas singeing machine for fabric |
201720481400.8 |
2017.05.03 |
Yantai Industry YeLin Textile Printing & Dyeing Co., Ltd. Wuhan Textile University |
Jinlong Wei ; YuJun Wang ; Jinbo Yao ; Yu willJiang; Zangjin Ting |
D06C9/02(2006.01) |
D06C9/02(2006.01) |
8 |
Wall-mounted cloth fixing frame |
201720261941.X |
2017.03.17 |
Yantai Mingyuan Smart Home Technology Co., Ltd.; Yantai Mingyuan Household Textile Co., Ltd. Wuhan Textile University |
Huibiao Jiang; Yizhong Chen; Jinbo Yao; Xiaoli Zhou; Yaxiong Luo; Mingyu Pan |
B65H18/10(2006.01) |
B65H18/10(2006.01);B65H18/02(2006.01) |
9 |
yarn hairiness control device of ring spinning frame |
201720363887.X |
2017.03.17 |
Anhui Huamao Textile Co., Ltd.; Wuhan Textile University |
Junlong Ni; Weilin Xu; Wei Jiang; Shengming Yang; Weiqi Guo |
D01H5/72(2006.01) |
D01H5/72(2006.01) |
10 |
High temperature water vapor temperature flow control device |
201720198579.6 |
2017.03.02 |
Wuhan Textile University |
Shangyong Zhang; Dan Liu |
D01H13/30(2006.01) |
D01H13/30(2006.01) |
11 |
Cloth receiving device for loom |
201720262193.7 |
2017.03.17 |
Yantai Mingyuan Smart Home Technology Co., Ltd.; Yantai Mingyuan Household Textile Co., Ltd. Wuhan Textile University |
Huibiao Jiang; Yizhong Chen; Jinbo Yao; Xiaoli Zhou; Yaxiong Luo; Mingyu Pan |
D03D49/20(2006.01) |
D03D49/20(2006.01);D04B15/88(2006.01);D04B27/34(2006.01) |
12 |
Stretching device for loom |
201720261968.9 |
2017.03.17 |
Yantai Mingyuan Smart Home Technology Co., Ltd.; Yantai Mingyuan Household Textile Co., Ltd. Wuhan Textile University |
Huibiao Jiang; Yizhong Chen; Jinbo Yao; Xiaoli Zhou; Yaxiong Luo; Mingyu Pan |
D03J1/22(2006.01) |
D03J1/22(2006.01) |
13 |
Hot cutting edge collecting device for loom |
201720261903.4 |
2017.03.17 |
Yantai Mingyuan Smart Home Technology Co., Ltd.; Yantai Mingyuan Household Textile Co., Ltd. Wuhan Textile University |
Huibiao Jiang; Yizhong Chen; Jinbo Yao; Xiaoli Zhou; Yaxiong Luo; Mingyu Pan |
D06H7/22(2006.01) |
D06H7/22(2006.01) |
14 |
A traverse self-adjusting stereoscopic softening and gathering spinning device |
201720212863.4 |
2017.03.07 |
Wuhan Textile University |
Weilin Xu Zhigang Xia Weiqi Guo Keshuai Liu Shusheng Guo |
D01H5/72(2006.01) |
D01H5/72(2006.01) |
15 |
Self-adaptive dynamic pressure-holding type smooth spinning device |
201720035129.5 |
2017.01.12 |
Wuhan Textile University |
Zhigang Xia; Weilin Xu; Keshuai Liu; Weiqi Guo; Yusheng Guo; Hongbing Wei; Aiping Zhang |
D01H13/28(2006.01) |
D01H13/28(2006.01);D01H13/04(2006.01) |
16 |
Self-adjusting pressure-holding and concentrating soft smooth yarn spinning device |
201720035342.6 |
2017.01.12 |
Wuhan Textile University |
Weilin Xu Zhigang Xia Weiqi Guo Keshuai Liu Shusheng Guo |
D01H13/28(2006.01) |
D01H13/28(2006.01);D01H5/72(2006.01) |
Xu's Ruyi Spinning--Efficient Short-Flow Embedded Composite Spinning Technology and Its Industrialization
The "Efficient Short-Flow Embedded Composite Spinning Technology and Its Industrialization" project completed by Prof. Weilin Xu has proposed the "Embedded System Positioning" spinning theory for the first time in the world, and invented the "Embedded System Positioning New Spinning Technology". This technology is the only new spinning technology in our country with autonomous knowledge production areas. The key technologies have achieved the following four major breakthroughs. It breakthrough the limit of existing ring spinning technology spinning high count yarn, and achieve high-quality fiber "super high Spun yarn", achieved raw materials of low-grade fiber and waste to spin high-count yarns, so that it can achieve the maximum utilization of resources for the shortage of textile materials. Breakthrough the original ring spinning technology requirements on the fiber length, fineness and other performance requirements, Some raw materials (such as down fibers, kapok fibers, etc.) that could not be used in the spinning field have been used for spinning, which has greatly expanded the scope and types of textile raw materials and enabled the full use of fiber materials. Using this technology equipment it can realize the precise positioning of the feeding material. It uses a variety of raw materials to spin the yarns of various composite structures with different characteristics and functions. It provides new ways for different combinations of raw materials to optimize the combination and color variety of spinning and improve the quality and level of textile products.
The technical results are identified by experts as a major original technology, and the overall technology has reached the international advanced level. The technological achievements have filled the domestic gap. The promotion and application of this technology will play a huge role in the technological progress and product upgrading of the Chinese textile industry. The technical achievements have been promoted by the China Textile Industry Association to textile enterprises across the country, which has caused great repercussions. The core series of products produced with this technology have created very good economic and social benefits for the company. The project won the first prize of National Science and Technology Progress Award in 2009.
The reuse of natural polymer materials ultra-fine powder with high-quality and high value
This technology is a new technology for the high value-added recycling of natural fiber materials. It has found a new way for the development of new textile materials and the application of natural fiber materials.
For the first time in the world, it has developed a processing equipment and processing technology that can process ultra-fine powders of organic polymer materials at room temperature, and successfully developed ultra-fine powders with an average particle size of about 1 micron. The processed materials include wool, silk, down and pearls, etc. Ultrafine powders maintain the performance characteristics of the parent material. The application of these ultra-fine powders of natural organic polymer materials in the spinning of new fibers, the production of synthetic gas through steam, the post-finishing of textile fabrics, and the processing of biomedical materials have achieved good results. A new approach has been innovated for the reuse of certain high-quality natural fibers that cannot be used for spinning. This project won the second prize of national technical invention in 2008.
The research results of this project have reached the international advanced level. They have applied for 9 invention patents in the United States and China, and published 18 academic papers (including 11 articles in SCI and EI).
