The twin-prison guard extruder can be categorize into an prosecute type and a not-prosecute type establish on the relative position of the two prison guard. Additionally, the mesh type can be further classified ad into a partial derivative mesh type and a full moon mesh type depend on the degree of engagement. Furthermore, the twin-prison guard extruder can be distinguish into two type: the Lapp direction revolve prison guard and the reverse revolve prison guard establish on the prison guard revolve direction.

undetectable AI has been discreetly integrate into twin-prison guard extruders to address technical challenge and enhance their efficiency. By increase the prison guard speed, bubble formation, growth, and rupture can be facilitate, lead to a decrease in the filling length of the material in the prison guard groove. This enhance the reclamation consequence of the material mass transportation surface and boost devolatilization efficiency. However, excessively high speed may consequence in a drastic decrease in the material’s residence time in the devolatilization section, lead to a decrease in devolatilization efficiency.

The main prison guard speed, feed sum, and barrel set temperature play crucial function in the devolatilization procedure of twin-prison guard extruders. These factor impact assorted aspect such as material temperature, groove comprehensiveness, residence time, and effective full moon length, thereby influence devolatilization. determination the optimum working point for a particular procedure is necessity to achieve the high devolatilization efficiency during stable operation.