公开(公告)号：US20210198497A1

公开(公告)日：2021-07-01

申请号：US16850141

申请日：2020-04-16

Applicant: Qingdao University of Technology

Inventor： Yongjuan Geng ,  Shaochun Li ,  Dongshuai Hou ,  Zuquan Jin ,  Xu Chen ,  Qilong Xiao ,  Weifeng Zhang ,  Dongyi Lei ,  Jing Gao

IPC: C09D5/02 ,  C09D5/00 ,  C04B38/00

Abstract: A superhydrophobic coating is provided and contains organosilane, an inorganic nanomaterial, and an emulsifying agent. A mass proportion of the components is controlled, so that the superhydrophobic coating can form a micro-nano mixed microstructure inside foam concrete. The organosilane first forms dense hydrophobic surface layers on the surface and in inner pores of the foam concrete, and the nanomaterial forms uniformly distributed nano-bulges on the hydrophobic surface layers formed by the silane. The superhydrophobic performance of the foam concrete can be effectively improved by combining the two microstructures. The foam concrete exhibits excellent superhydrophobic performance.

公开(公告)号：US20240174566A1

公开(公告)日：2024-05-30

申请号：US18280777

申请日：2023-02-09

Applicant: QINGDAO UNIVERSITY OF TECHNOLOGY

Inventor： Shaochun Li ,  Xu Chen ,  Mengjun Hu ,  Ang Liu ,  Yongjuan Geng ,  Jialin Jiang

IPC: C04B18/02 ,  C04B14/30 ,  C04B28/02 ,  C04B40/02

CPC classification number: C04B18/023 ,  C04B14/305 ,  C04B28/02 ,  C04B40/0231

Abstract: Provided are a nano-titanium dioxide (NT)/biochar (BC) composite, and a preparation method and use thereof, which belong to the technical field of cement-based materials. NT is introduced into a porous structure of the micron-sized BC, which not only addresses the high aggregation of NT, but also reduces Ca(OH)2 size and crystal growth orientation through effects such as filling and nucleation brought by NT in the porous structure of BC. In this way, more C—S—H gels are generated to fill the pores, thereby improving an interfacial transition zone (ITZ), which enhances the mechanical properties such as compressive strength and flexural strength. The NT/BC composite of the disclosure is doped into a cement-based material, which allows that in a surface layer of the cement-based material, CO2 absorption capacity could be improved through carbon sequestration properties and the porous structure of the composite, and the carbonization of the surface layer could be accelerated by hydration accelerating properties of the NT to form a calcium carbonate surface protective layer, thereby improving durability of the cement-based material.

公开(公告)号：US11312866B2

公开(公告)日：2022-04-26

申请号：US16850141

申请日：2020-04-16

Applicant: Qingdao University of Technology

Inventor： Yongjuan Geng ,  Shaochun Li ,  Dongshuai Hou ,  Zuquan Jin ,  Xu Chen ,  Qilong Xiao ,  Weifeng Zhang ,  Dongyi Lei ,  Jing Gao

IPC: C09D5/02 ,  C04B38/00 ,  C09D5/00 ,  C04B103/48 ,  C04B103/65

Abstract: A superhydrophobic coating is provided and contains organosilane, an inorganic nanomaterial, and an emulsifying agent. A mass proportion of the components is controlled, so that the superhydrophobic coating can form a micro-nano mixed microstructure inside foam concrete. The organosilane first forms dense hydrophobic surface layers on the surface and in inner pores of the foam concrete, and the nanomaterial forms uniformly distributed nano-bulges on the hydrophobic surface layers formed by the silane. The superhydrophobic performance of the foam concrete can be effectively improved by combining the two microstructures. The foam concrete exhibits excellent superhydrophobic performance.