DE19717257A1 - Method of manufacturing cellulosic bodies using coagulation bath - Google Patents

Abstract

Cellulosic bodies are shaped in a warm state from a solution of cellulose in a tertiary amino-oxide and exposed to a gas stream before entering a coagulating bath. The gas stream is turbulent with a degree of turbulence of at least 1%. The gas stream has a degree of turbulence of between 1 deg and 5 deg . The gas flow is in a direction normal to the solution.

Description

The invention relates to a method for producing cellulose Shear molded body by a solution of cellulose in a ter tertiary amine oxide is formed in a warm state and before incorporation is exposed to a gas stream in a precipitation bath.

WO 95/01470 discloses a method for producing cellu Loose fibers from a solution of cellulose in one ter tertiary amine oxide, such as N-methylmorpholine-N-oxide (NMMO). The cellulose solution is extruded through a spinneret diert, and the fiber-shaped solution is then in stretched and cooled in the so-called air gap and then in a coagulation bath of the cellulose was introduced. At the Method of WO 95/01470 a gas stream is used for cooling which is substantially laminar, i.e. H. if possible none Has turbulence.

The characterization of currents is often used Reynolds number used, which is small for laminar flows is less than 2320. Alternatively, to describe the flow the degree of turbulence, which is defined as the quotient from the root of the middle quadratic fluctuation rate and the mean Flow velocity. For a laminar flow is the degree of turbulence is about 0.05% (H. Schlichting,  "Grenzschichttheorie", publisher G. Braun 5th edition 1965, pages 530, 531).

With the measure of an essentially laminar gas flow should be achieved in WO 95/01470 that using a dense thread structure in a spinneret with a high hole density can be spun, the textile properties of the ge spun threads can be adjusted better. Especially be the low achievable thread is emphasized in this context fineness.

The present invention has for its object a Ver drive to the production of cellulosic moldings by a Warm cellulose solution in a tertiary amine oxide is formed and one before being placed in a precipitation bath Exposed to gas flow to provide one has high spinning stability.

This object is achieved in the method mentioned by that the gas flow is turbulent and a degree of turbulence of min at least 1%.

In particular, the gas flow has a degree of turbulence of 1 to 8%, preferably I to 5% and in particular 1.35 to 2%.

It is advantageous if the gas flow is essentially vertical is directed at the shaped solution.

Within the scope of the present invention, shaped bodies include or filaments, but also membranes, such as Hollow fibers or flat membranes, or films.

The degree of turbulence of the gas flow is measured in frames of the present invention with a laser Doppler anemometer Type 5490 A, which was purchased from DANTEC, Ettlingen (Manufacturer: ION TECHNOLOGY, Salt Lake City). The device works  contributes with an argon ion line laser (linearly polarized) a wavelength of 514.5 nm. With this device a punk current, multidimensional measurement of unsteady flow speeds possible, the measurement being contactless and without probes interfering with the flow.

The measurement of the degree of turbulence of the flowing in the air gap Gases, such as air, occurred during the spinning process. The laser Doppler anemometer was used in conjunction with the Aus value program CDB "Breast 3.0" operated by the same supplier ben, and the degree of turbulence could thus be determined online.

In the following, the invention is illustrated by examples purifies and describes.

A solution of 14% by weight cellulose, 74.9% by weight NMMO, 11% by weight Water and 0.1% by weight propyl gallic acid as stabilizer was with a spinneret with 50 or 100 nozzle holes at egg ner temperature between 110 and 115 ° C extruded into fibers. The molded cellulose solution was then placed in an air gap stretches and coagulates in an aqueous bath. Subsequently the fibers were washed, dried and wound up.

The fibers were blown with air in the air gap. The fiber bundle, consisting of 50 or 100 individual fibers or filaments, was blown with air in the air gap from the side, i.e. essentially vertically, over the blowing length (ABL in mm), which had a temperature of 14 to 25 ° C and whose degree of turbulence was determined with the laser Doppler anemometer and evaluation program described above. In the table below, in which the examples with the numbers 1 to 3 are comparative examples and the numbers 4 to 8 are examples according to the invention, n means the number of filaments, T the filament titer in dtex, LST the air gap depth in mm, including the dimension of the Filament bundle is to be understood perpendicular to the filament bundle and thus parallel to the blowing direction, i.e. the distance that the blowing has to penetrate. SG represents the spinning speed in m / min. The abbreviation TBG denotes the degree of turbulence in% and SSE the number of spinning defects per single filament in l / h. To determine this size, the running time without spinning disturbances was measured in continuous spinning tests. After a spinning disturbance occurred, for example in the form of filament tears in the air gap, the yarn was spun again and the time was measured again. For each of the following examples, the mean t of these times was used to calculate the number of spinning failures per hour per single filament according to the equation:

SSE = 1 / (tn)

calculated, where n represents the number of nozzle holes of the nozzle used in the spin, that is the number of filaments.

In Comparative Example 1, in which the filaments are a gas were exposed to only a degree of turbulence of 0.82% indicated, spinning was not possible. With a degree of turbulence of 0.85% (comparative example 2), spinning was possible However, the number of spinning disorders was still 0.1 l / h. You sit down on the other hand, air with a degree of turbulence greater than 1% occurs a significant decrease in spinning disorders. This must be as be considered very surprising since one would expect that  the presence of turbulence in the air gap The surrounding gas flow negatively affects the spinning stability effect and thus an increase in spinning disorders leads. So - as shown in Example 8 - with a Turbu Lenzgrad of 1.45% even at a spinning speed of 800 m / min can be spun easily.

Claims (4)

1. A process for the production of cellulosic moldings by molding a solution of cellulose in a tertiary amine oxide in the warm state and, prior to introducing it into a precipitation bath, it is exposed to a gas stream, characterized in that the gas stream is turbulent and has a degree of turbulence of at least 1%. 2. The method according to claim 1, characterized in that the Gas flow has a degree of turbulence of 1 to 8%, in particular 1 has up to 5%. 3. The method according to claim 1 or 2, characterized in that the gas flow has a degree of turbulence of 1.35 to 2% points. 4. The method according to claim 1, 2 or 3, characterized net that the gas flow is substantially perpendicular to the ge shaped solution is directed.