Polyimide film(equivalent Kapton) is a high temperature resistant item.
The high temperature adhesive label for PCB industry bar code, it is one side with a special coating for ribbon printers,the other side is permanent acrylic adhesive. This label can resist upto 350C high temperature. Mother roll is supplied in width 500mm.Slitting service can be offered.
ESD anit static type is offered, both sides(printing side and adhesive side) are anti static with resistance 10E7.
Customized color label is available.
The high temperature hang tag(up to 500C dedgree) is both sides matte coated,suitable for ribbon, thermo transfer ,digital printing, as a hang tag in steel industry or other high temp. environment. Mother roll width is supplied in 500mm, slitting service is offered.
Pi Hang Tag Label,Pi Adehesive Label Roll,Polyimide Hang Tag,Pi High Temperature Label Mianyang Prochema Commercial Co.,Ltd. , https://www.gustek.com
POLYIMIDE HIGH TEMPERATURE LABEL & TAG
The project titled "Comprehensive Utilization and Development of Fly Ash in Zhungeer Mining Area," led by Dr. Pan Aifang from Chang’an University, has recently been recognized by an expert panel. This groundbreaking research has the potential to boost the overall utilization rate of fly ash beyond 90%, offering significant economic returns through the production of valuable products like alumina and silica.
Traditionally, most methods convert fly ash into construction materials, which not only leads to the loss of important resources such as aluminum and rare earth elements but also incurs high processing costs. To address this issue, Shenhua Group Zhungeer Energy Co., Ltd. partnered with Chang’an University to develop more efficient and sustainable solutions. After over a year of dedicated research, they successfully developed an aluminum oxide extraction process for pulverized coal fly ash and a carbon dioxide recovery method from sintering furnace waste.
In addition, seven other research outcomes were achieved, including the use of fly ash residue for building materials and advanced techniques for extracting alumina and silica. The team conducted experiments in a laboratory setting, where they extracted alumina from pulverized coal, furnace dust, and coal ash. They then used silica gel to separate silica, employing a water-acid combined step-by-step elution method to improve the efficiency of the extraction process. This new technique represents a major innovation in the field.
Currently, the technology is undergoing further refinement and is being prepared for broader application. With its potential to transform waste into valuable resources, this project marks a significant step forward in the sustainable management of industrial by-products.