KR20090108599A - Forming solutions - Google Patents

Abstract

The invention relates to a method of manufacturing a solution of cellulose in an aqueous organic solvent by treatment of a premix containing cellulose, water and an organic solvent for cellulose. The premix is pumped with a pump through a supply line into a vertically orientated thin film evaporator having a centrally located rotor adapted to wipe the premix over the interior of the thin film evaporator and to transport it downwards through the evaporator. The method is characterised in that the premix is forced by the pump into the thin film evaporator in a controlled manner and is not substantially pulled into the thin film evaporator in an uncontrolled manner by the pressure difference between the supply line for the premix and the interior of the thin film evaporator.

Description

Molding solution {FORMING SOLUTIONS}

The present invention relates to a process for preparing a solution of cellulose in an aqueous organic solvent. The present invention relates in particular to a process for the preparation of a solution of cellulose used in the preparation of lyocell fibers.

Methods for making lyocell fibers are well known techniques. Essentially cellulose in pulp form is mixed with water, an organic solvent for cellulose and a stabilizer. By the action of heat and reduced pressure, part of the water is evaporated to produce a solution of cellulose in an organic solvent, which also contains the remainder of the water. Next, the solution is sent to a spinning process so that the solution is formed into a molded article, typically a filament, which is then treated to elute an aqueous organic solvent, whereby cellulose precipitates out as a precipitate to form a cellulose molded article.

Since staple fibers are products used in large quantities, the fiber manufacturing process is manufactured at a cost economically viable for artificial fibers such as cellulose fibers or polyester fibers, such as cotton or biscose fibers, which are subject to competition. It should be a process that can be done.

This means that the economics of the process, in the production of lyocell fibers, in particular lyocell staple fibers, should be such that the apparatus used for the preparation of the solution is capable of producing a solution in quantities of thousands of tonnes per year.

The need to manufacture fibers on a large scale requires the adoption of a special manufacturing process for cellulose solutions. In an alternative process, cellulose and water and / or organic solvents are mixed together in an amount that can be directly dissolved. However, it is very difficult to do this on a large scale. In another process that is currently commercialized and associated with the present invention, a premix of cellulose, stabilizer, excess water and organic solvent is prepared and then excess water is used to concentrate the organic solvent so that the cellulose can be dissolved. Heating to evaporate.

The most successful type of device for preparing solutions by this commercialization process is the vertically oriented thin film evaporator available under the trade name Filmtruder manufactured by Buss AG. Patent Document EPO356419-A discloses a thin film evaporator of a form to which the present invention can be applied. In this patent, the premix is pumped through the inlet to the thin film evaporator and partially falls along the thin film evaporator by the action of gravity, but is forced downwardly conveyed mainly by a transport blade attached to the central rotor. The inner surface of the thin film evaporator is heated and a vacuum is applied to evaporate excess water. This produces a solution of cellulose in an aqueous solvent and is discharged by a pump from the thin film evaporator through the outlet. A preferred form of organic solvent is N-methyl morpholine-n-oxide, commonly abbreviated NMMO.

Cellulose solutions prepared by thin film evaporators can be used to produce various types of products. The main product made from such cellulose solution is cellulose fiber. However, various other cellulosic materials such as films, sponges or tubes can also be made.

One of the characteristics when the thin film evaporator is used for the preparation of the cellulose solution is that the opacity of the heating jacket and the premix is combined so that the inside of the thin film evaporator cannot be seen.

For most uses, the solution of cellulose produced by the thin film evaporator should be a clear yellow solution in which all cellulose fibers obtained from the premix are dissolved in aqueous NMMO. However, when a poor solution of cellulose is produced, for example a solution containing undissolved cellulose, it can be very difficult to determine the factors that caused the production of incompletely dissolved cellulose.

According to the present invention, it has been found that a thin film evaporator such as disclosed in Patent Document EPO356419-A can be operated to increase the reliability of the thin film evaporator to produce a solution in which almost all cellulose is dissolved in aqueous NMMO.

According to the present invention, as a method for producing a solution of cellulose in an aqueous organic solvent,

(i) forming a premix containing cellulose, water and an organic solvent for cellulose,

(Ii) swelling the cellulose in the premix with water and / or the solvent,

(Iii) pumping the premix into a thin film evaporator in a vertical orientation through a feed line using a pump, wherein the thin film evaporator causes the premix to flow down and forward downward through the evaporator. Having a centrally located rotor installed,

(iv) applying heat to the wall of the thin film evaporator to lower the internal pressure of the thin film evaporator to below atmospheric pressure,

(v) said step of evaporating a portion of the water such that said cellulose is dissolved into a solution in said aqueous organic solvent, and

(vi) withdrawing the solution of cellulose in the solvent from the bottom of the thin film evaporator

Including,

The premix is forced into the thin film evaporator by the pump in a controlled manner and substantially enters the thin film evaporator in a manner not controlled by the pressure difference between the supply line for the premix and the interior of the thin film evaporator. There is provided a method for producing a cellulose solution, which is characterized in that it is not.

One method of controlling pumping the premix into the thin film evaporator such that the premix is not substantially introduced by low pressure in the thin film evaporator is to have a premix feed line constriction proximate to the inlet of the thin film evaporator. . This shrinkage can be a permanently installed shrinkage, such as a narrowing of the premix feed pipe. Alternatively, the constriction can be a variable constriction, for example a valve which can be narrowed, especially during startup of the thin film evaporator, and then opened once the normal operating conditions are stabilized.

Alternatively, the pump itself may be installed close to the inlet so that the premix cannot be sucked into the thin film evaporator at all. If the pump is far from the inlet of the thin film evaporator, for example at least 2 meters, a certain volume of premix can accumulate in the pipe and can therefore be sucked up, especially in the startup phase.

The thin film evaporator may have an internal heating surface area in the range of 5 to 45 m 2.

To illustrate, embodiments of the present invention will be described below with reference to the accompanying drawings.

1 is a schematic cross-sectional view of a thin film evaporator according to the disclosure of the patent document EPO356419-A.

2 is a schematic cross-sectional view of an inlet pipe with one form of shrinkage.

3 is a schematic cross-sectional view of an inlet pipe having a second form of shrinkage;

4 is a schematic cross sectional view of an inlet pipe having a third form of shrinkage;

1 is a diagram described in the publication of EPO356419, and FIGS. 2 to 4 show different ways to control the flow of premix entering the thin film evaporator.

Commercial methods of forming solutions of cellulose from aqueous NMMO solutions are known and are outlined here as background art. Essentially, a premix of water, cellulose and NMMO as well as stabilizers such as propyl gallate are prepared and left. This causes the cellulose to swell with the aqueous NMMO. Typically, the solution is a mixture of 60% NMMO and 40% water mixed with cellulose and a small amount of propyl gallate, the final concentration of cellulose being about 13% by weight after the excess water is evaporated. The suspension is generally pumped through the inlet 11 into the interior of the thin film evaporator shown in FIG. 1. On the center shaft 7 rotated by the electric motor 6, a spreader disk 10 is provided on the opposite side of the inlet 11 in the axial direction. The spreader disc forces the premix down. The premix is moved downward by being pushed by the transport blade 8 mounted to the shaft 7 with the action of gravity. The blade is inclined at an angle with respect to the longitudinal axis of the shaft, and the motor 6 rotates in the direction of pushing the premix downward when the blade is in contact with the premix. Under the action of the blades and gravity, the premix passes downward from the opposite position of the inlet 11 through the thin film evaporator.

The heating jacket 2 surrounds the cylindrical thin film evaporator and the heating fluid passes through the thin film evaporator from the inlet 4 to the outlet 5 via the passage 3. As a result, the inner wall of the thin film evaporator is heated by the flow medium passing through the heating jacket. Typically, steam at 130 ° C. is used as the heating medium.

The interior of the thin film evaporator is typically maintained at a low internal pressure of 100 millibars by drawing the gaseous contents of the thin film evaporator through the outlet opening 14 by a suitable vacuum pump.

The water in the NMMO mixture is evaporated by a combination of heating through the jacket 2 and low internal pressure. This evaporation results in a gradual concentration of the NMMO and reaches a concentration capable of dissolving cellulose as the NMMO is concentrated. This process continues down the entire length of the thin film evaporator to form a clear yellow cellulose solution, which is pumped out of the bottom of the thin film evaporator through outlet 12. The entire assembly is symmetric about the center line 9 except for the inlet and outlet pipes such as 11, 14, 4 and 5. Inside the bottom of the thin film evaporator, a supporting cone 14 supporting the bottom of the rotor is provided. The blade 8 is spaced apart from the inner wall of the thin film evaporator by a small gap indicated by reference numeral 13.

It has now been found that the quality of the solution formed by the thin film evaporator can be improved by installing a restriction for the premix feed near the inlet 11. Examples of such limitations are illustrated in FIGS.

As can be seen in this figure, the thin film evaporator used to form the cellulose solution can be any type of thin film evaporator, and the operation of the thin film evaporator is left to the discretion of the user of the present invention.

In practice, installations that include thin film evaporators are typically large, complex structures, in which a significant amount of piping connects various inlets and outlets, such as inlet 11. The premix is produced at a location relatively close to the thin film evaporator, but due to the size of the opening and the number of components required, there are usually several meters of pipe between the premix supply system and the inlet of the thin film evaporator. The distance between the pump and the inlet point can reach several meters. The premix has to be transferred to a pump because it has a low viscosity because of the viscosity of the pasty mixture of cellulose in the mixture of water and amine oxide. Suitable pumps for pumping premixes are piston pumps or Netzch Nemo Mono pumps. Such a pump not only introduces the premix, but also meteres or pumps in a controlled manner the premix entering the thin film evaporator for proper control of the dissolution process.

A pump, such as pump 20 in FIG. 2, is connected to the inlet 11 via a suitable pipe 21. 2 shows a throttle valve 22. Prior to the present invention, the throttle valve 22 was not installed and the pump 20 was connected directly to the inlet 11 via a pipe 21, which could be of indefinite length and usually had a length of several meters.

In some cases, it has been found that during operation of the thin film evaporator, some of the cellulose is transported in an undissolved state so that the solution exiting the outlet 12 of the thin film evaporator contains a high concentration of undissolved cellulose. Although inevitably a small amount of undissolved cellulose is always present, it can be easily removed by filtration. The greater the amount of cellulose present in the solution, the more filtration processes are needed and the more often the filters have to be replaced. Therefore, it is clear that the higher the purity of the solution produced by the thin film evaporator, the more desirable.

As such, it has been found that by installing the shrinkage 22 in the pipe 21 a solution of improved quality can be produced by the thin film evaporator. The reason is that the slug of the premix is sucked into the thin film evaporator, overloading the distribution ring and the upper transport blade and causing the slug to be transported through the system, resulting in the partial dissolution of cellulose. It is considered that this is because the shrinking portion 22 prevents the low pressure in the thin film evaporator which will precipitate in the solution 12. In particular, during the start up of the process, it has been found that slugs of cellulose can be sucked into the center of the thin film evaporator, so that a variable shrinkage valve has been found to be the preferred means of narrowing the tubing 21. In addition, it has been found that after the thin film evaporator is operated in a steady state, in some cases, opening the contraction valve 22 can reduce the load on the pump 20 and thus reduce the pumping cost.

Although the variable shrink valve 22 is a preferred device for carrying out the method of the present invention, it is also desirable to provide a shrinkage 32 in the pipe 21 between the pump 20 and the inlet 11. Found that you can get The shrinkage can be an opening plate with an orifice of a suitable size. The orifice may be round, oval or rectangular. The orifice may be combined with a valve to increase shrinkage at startup.

Another method of obtaining the desired result of the present invention is to install the pump 20 in a position close to the inlet 11 of the thin film evaporator. The problem in this case, however, is that the layout of the thin film evaporator and premix pumping assembly is severely constrained, and because the thin film evaporator is a large heating assembly, it can be difficult to install the pump in close proximity to it. Therefore, this form of the invention is only available if plant layout is allowed.

The shrinkage also helps to prevent dehydration of the premix as it enters the thin film evaporator. This may result in a plug of material that results in blocking of the supply line. In addition, the shrinkage also helps to prevent air from entering the feed line due to the pressure difference between the interior of the thin film evaporator and the premix in the feed line.

Claims (7)

As a method for producing a solution of cellulose in an aqueous organic solvent, (i) forming a premix containing cellulose, water and an organic solvent for cellulose, (Ii) swelling the cellulose in the premix with water and / or the solvent, (Iii) pumping the premix into a thin film evaporator in a vertical orientation through a feed line using a pump, wherein the thin film evaporator causes the premix to flow down and down through the evaporator Having a centrally located rotor installed to feed in a direction; (iv) applying heat to the wall of the thin film evaporator to lower the internal pressure of the thin film evaporator to below atmospheric pressure, (v) said step of evaporating a portion of the water such that said cellulose is dissolved into a solution in said aqueous organic solvent, and (vi) withdrawing the solution of cellulose in the solvent from the bottom of the thin film evaporator Including, The premix is forced into the thin film evaporator by the pump in a controlled manner and substantially enters the thin film evaporator in a manner not controlled by the pressure difference between the supply line for the premix and the interior of the thin film evaporator. Method of producing a cellulose solution, characterized in that not. The method of claim 1, Wherein said control is effected by constriction in a premix feed line proximate to the inlet of said thin film evaporator. The method of claim 2, A method for producing a cellulose solution, wherein the shrinkage portion is a fixed shrinkage portion. The method of claim 2, The said shrinkage part is a variable shrinkage part, The manufacturing method of the cellulose solution. The method of claim 1, And the feed pump is located adjacent the thin film evaporator. The method according to any one of claims 1 to 5, Wherein said thin film evaporator has an internal heating surface area in the range of 5 to 45 m 2. The method of claim 4, wherein And wherein said variable shrinkage portion is used to inhibit flow only upon startup of said process.

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