Abstract
In this paper, we report new results related to the development of a novel regenerated cellulose fiber process of the Lyocell type, denoted Ioncell™, and characterized by the use of a powerful direct cellulose solvent, 1,5-diaza- bicyclo[4.3.0]non-5-enium acetate ([DBNH][OAc]) a superbase-based ionic liquid (IL). The focus of this work is on the effects of air gap conditioning (AGC) during the dry-jet wet spinning operation. The installation of an AGC system on the spinning line led to significant improvements of the fiber properties. The fiber titer variation decreased significantly, and the fiber toughness increased by approximately 50% when controlling the temperature and the relative humidity in the airgap using a convective air flow. The presence of water vapor in the air stream was a determinant factor for the improvement of the fiber elongation. The interaction of water vapor with the spinning dope was investigated using dynamic vapor sorption. The diffusion coefficient of water vapor inside the dope could be identified from those experiments and used in a numerical simulation model of the heat and water vapor transfer in the air gap between the spinning dope and the surrounding air. The experimental and simulation results suggest that dope convective cooling and surface hydration lead to a higher fiber toughness.
Highlights
IoncellÒ is a new Lyocell-type process to produce man-made cellulosic fibers (MMCFs). It is based on the direct dissolution of a cellulose substrate, preferably a dissolving pulp, in an ionic liquid (IL), air gap (AG) spinning of the solution in a water bath, and a subsequent solvent recovery step in which the IL, H2O and impurities generated are separated
We found that the washing behavior of IL is similar to that of NMMO, so that similar IL residual values of about 50–500 ppm can be expected
We showed the importance of the air gap conditioning (AGC) during the spinning operation in order to enhance the fiber properties
Summary
IoncellÒ is a new Lyocell-type process to produce man-made cellulosic fibers (MMCFs). It is based on the direct dissolution of a cellulose substrate, preferably a dissolving pulp, in an ionic liquid (IL), air gap (AG) spinning of the solution (spinning dope) in a water bath, and a subsequent solvent recovery step in which the IL, H2O and impurities generated are separated. The AG is the vertical distance separating the exit of the spinneret and the coagulation bath surface It is an important part of Lyocell-type dry-jet wet spinning processes and allows the simultaneous use of a spinneret at 70–90 °C and a coagulation bath at 10–20 °C. The incipient filament can be stretched in the AG This so-called draw creates a uniaxial stress tensor in the filament and results in pronounced polymer orientation. The resulting fibers have good mechanical properties and linear density values suitable for both textile and technical applications
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