DD284034A5 - METHOD FOR THE PRODUCTION OF SOLUTIONS OF CELLULOSE AND DEVICE FOR CARRYING OUT THE PROCESS - Google Patents

Abstract

For producing solutions of cellulose in water-containing tertiary amine oxides from a suspension of cellulose in an aqueous solution of the tertiary amine oxide by supplying heat under reduced pressure, the suspension having a viscosity between 50 and 15,000 Pas.sec, measured in a relative system, is spread as a layer or film over a heating surface and transported until a homogeneous solution of the cellulose is formed, the feeding of the suspension and the take-off of the homogeneous solution being carried out continuously. These solutions can be produced in an indirectly heated vessel which is provided with a stirring device and can be evacuated and which is designed as a cylindrical container (2) with a centrally mounted stirrer shaft (7) and stirrer blades (8) attached thereto, the radial distance (13) of the stirrer blades (8) from the inside wall (1) of the container (2) being at most 20 mm, and an inlet (11) for the cellulose suspension being provided in the upper part of the container and an outlet (12) for the homogeneous cellulose solution being provided at the lower end. <IMAGE>

Description

Process for the preparation of solutions of cellulose and device for carrying out the process

Field of application of the invention

The invention relates to a process for the preparation of solutions of cellulose in aqueous tertiary Aminoxlden from a suspension of cellulose in an aqueous solution of the tertiary amine oxide by supplying heat under reduced pressure, and a device for carrying out the method. Field of application is the production of viscose.

Characteristic of the known state of the art

Such a method is described in PCT Publication WO 83/04415. Thereafter, the cellulose is suspended in an aqueous solution of a tertiary amine oxide containing up to 40 mass ^ water and heated with stirring at temperatures between 90 and 120 ⁰ C. At the same time the pressure is reduced to 80 to 150 mbar and as long withdrawn water until the, cellulose goes into solution. In this way, spinnable solutions can be produced with up to 15% by mass of cellulose.

By molding these solutions in water, cellulose-based films, filaments or moldings are obtained, that is to say, articles which are today produced to a large extent by the viscose process. However, spinnable solutions of cellulose in aqueous tertiary amine oxides have a decisive advantage with regard to environmental compatibility with respect to the viscose: While during spinning, the tertiary amine oxide, such as

can be recovered and reused, arises when decomposing the viscous H ₂ S * COS, CS ₂ and colloidal sulfur These substances can be disposed of only with difficulty.

Nevertheless, eich has not been able to enforce the abovementioned process with tertiary amine oxides as a solubilizer "since it still has a number of disadvantages.

Thus, poor water can be withdrawn in a stirred tank due to the unfavorable ratio of liquid surface to liquid volume, resulting in long residence times in the range of 2 to 4 hours in a stirred tank. During this time, there is a partial degradation of the polymeric cellulose chain, which is still favored by the elevated temperature. This partial degradation in turn adversely affects certain properties of the final products after the spinning process, such as. B. on their strength, their elongation and Schiingenfestigkeit. It is also known that, in particular when heated above 130 ^° C., strong discoloration may occur as a result of decomposition of the amine oxide used. This decomposition may occur in some compounds, such. As N-methyl-morpholine N-oxide, even explosively run with vigorous evolution of gas, so that the solutions present in the stirred tank pose a security risk due to their amount.

In a large-scale implementation of the method should therefore be used appropriately protected with high pressure autoclave when using stirred tanks, which are not suitable for continuous operation for economic reasons. On the other hand, in the stirred tank and

without safety device only a discontinuous operation possible, whereby the flexibility of the method is very low because parameters such. As temperature and evaporation rate, difficult to change. Added to this is that due to the high viscosity of the cellulose solutions much dope is retained by the stirred tank, which makes both the cleaning of the boiler more difficult and the economy further deteriorates.

Object of the invention

The inventive method allows a large-scale and continuous production of cellulose solutions, which can be used without high-pressure autoclave can. The unwanted decomposition of the tertiary amine oxide and degradation of the cellulose can be largely prevented.

Explanation of the essence of the invention

The present invention has for its object to overcome the disadvantages of the known technical solutions and to provide a method for the production of cellulose solutions in aqueous tertiary amine oxides available that can be carried out continuously, the heat treatment of the suspension should be much shorter to the minimize thermal stress on the cellulose and the tertiary amine oxide. In addition, the inherent in the prior art security risk should be avoided. Another object of the invention is to provide a device for carrying out the method, which does not have the disadvantages associated with the stirred tank or with high-pressure autoclave.

This object is achieved in that the suspension layer of a heating surface or film-like * is transported until a homogeneous solution of cellulose is formed, which has a viscosity between 50 and 15 * 000 Pas.see, the supply of the Suspension and the withdrawal of the homogeneous solution is carried out continuously.

The layer or film-like spread of the cellulosic suspension over the heating surface leads to a large liquid surface, which facilitates the removal of water. At the same time it allows a rapid heating of the suspension to the temperature necessary for the preparation of the solution. Through the transport over the heating surface, a permanent mixing of the suspension is achieved, which further accelerates the heat and mass transfer.

To adjust the viscosity of the solution, which is measured in the relative system, and to influence the swelling behavior of 'cellulose in the suspension, a diluent, such as. As ethanol, are added to the suspension.

A particularly good mixing is achieved if the spread over the heating surface layer has a maximum thickness of 20 mm, preferably 1.5 to 5 mm.

Advantageously, tertiary amine oxide is N-methyl

morpholine-N-oxide, preferably in an aqueous solution of 40% water.

A preferred embodiment of the method according to the invention is characterized in that the suspension is brought to a temperature between 50 and 15O ⁰ C, preferably between 60 and l00 ° C and a pressure of 0.5 mbar to 1000 mbar, preferably 50 mbar to 150 mbar , is suspended.

It has proved to be particularly favorable, if the suspension is kept in contact with the heating surface for a period of 1 minute to 60 minutes. This period of time is on the one hand sufficient to produce a homogeneous solution, and on the other hand so short that a decomposition of the tertiary amine oxide and degradation of the cellulose can be largely prevented.

An appropriate device for carrying out the method according to the invention, with iinjni indirectly heated, provided with a stirring device and evacuated vessel, characterized in that the vessel is designed as a cylindrical container with a centrally mounted stirrer shaft and attached thereto stirring blades, wherein the radial distance of the stirring blade In to the inner wall of the container is a maximum of 20 mm and in the upper part of the container an inlet for the Ce I Iulosesuspension and in the lower end an outlet for the homogeneous Ce I lulose solution is provided.

An advantageous embodiment of the invention Device has a distributor ring on the agitator

layer or film spread of the

Ce LLu loose suspension on the inner wall of the container.

To control the transport of the Ce LLuLosesuspension along the inner wall of the container, it has proved to be advantageous if the stirring blades to the axis of the agitator shaft have an angle of inclination, which is adjustable in size.

The method according to the invention which can be carried out with the device according to the invention is extremely flexible with respect to a change in the operating parameters and has a much lower safety risk than the prior art, since not a large amount of solvent is heated at once, but always by the layer-like spread over the heating surface only a comparatively small amount.

The device according to the invention is illustrated in more detail with reference to FIGS. 1 and 2, wherein Fig. 1 shows a partial longitudinal section of the device according to the invention and Fig. A section along the line II-II of Fig. 1 in an enlarged scale.

1, the inner wall of a preferably upright rotating body is designated, which is formed in the illustrated embodiment almost over the entire length as a cylindrical container 2. The inner wall 1 is largely surrounded by a heating jacket 3 with terminals 4 and 5 for the heating medium, the terminal 4 of the supply of the heating medium and the terminal 5 serves its discharge.

Centrally in the container 2 is a stirring shaft 7 driven by the motor 6 with an agitator blade 8 inserted in it

stored. The stirring blades 8, which are flat in the illustrated embodiment, extend radially to the axis, with their plane having an angle of inclination alpha to the axis 9 of the agitator shaft 7, the size of which is preferably adjustable. Over the stirring blades 8, a distribution ring 10 is attached to the tube shaft 7, which spreads the introduced through the inlet 11 Ce I IuLosesuspension on the inner wall 1 in layers. The distribution ring

10 is thus at the level of the inlet 11th

At the lower end of the container 2 is kege Istumpfförmig

tapered with an outlet 12 for the homogeneous

Ce I Lu loose solution. The stirring blades 8 have throughout Area of the container 2 is a constant radial distance

13 to the inner wall 1 of the container 2, which is a maximum of 20 mm.

At the upper part of the container 2, u.zw. above the plane of the distributing ring 10, an opening 14 is provided for evacuating the container 2 and for removing steam.

The function of the device is the following:

The Ce I Lulosesuspension is - optionally in pre-tempered state - continuously through the inlet

11 introduced into the container 2, which is under reduced pressure, there detected by the distribution ring 10, spread on the inner wall 1 and from the Stirring 8 in the indirectly heated inner wall 1, which serves as a heating surface, to the outlet 12 at the lower end of the container. 2 transported. For indirect heating are heat transfer media, such as water, oil or steam.

During the transport of the Ce L luLosesuspension along the indirectly heated inner wall 1, the suspension

heated, wherein at the same time evaporates water due to the reduced pressure, so that the tertiary amine oxide is concentrated au ^f until the cellulose goes into solution.

In Fig. 2 it can be seen in detail how the Ce I Lu losesuspension in the container 2 is processed. Shown is the stirrer shaft 7 together with stirring blade 8, inner wall 1 and heating jacket 3, wherein a direction of rotation of the stirrer shaft 7 was assumed in the clockwise direction and indicated by the arrow 7 '. The layer-like propagation or the thickness of the layer of Ce L Iu losesuspension is ensured by the radial distance 13 of the stirring 8 in the heated inner wall 1. Due to the rotational movement, bow waves from Ce I Lu loose suspension, which are shown schematically in FIG. 2, form on the stirring blade. In these bow waves - as indicated in Fig. 2 - circulated the Ce I LuLoseteilchen, said movement is also transferred to the spread on the inner wall 1 suspension layer. As a result, a constant redeployment and an intensive mixing of the suspension is ensured, which favors the heat and mass transfer significantly.

It is of crucial importance for the continuous conduct of the process according to the invention that the separated water vapor is withdrawn in countercurrent to the transport of the suspension. In addition, it is important to provide a sufficiently large vapor space 15 for a rapid withdrawal of the water vapor, which is given when the ratio of the length to the diameter Jes cylindrical part of the container 2 a value between 4 and 8 aufwei st.

The invention allows the production of Ce I Iu Lose solutions with up to 30 mass * cellulose. embodiments

The invention will be explained in more detail in the following examples.

Example 1:

A suspension of Vorhydrolysesulfatzellstoff (degree of polymerization ca, 1400) in an aqueous solution of N-methylmorpholine N-oxide having a water content of 40% by mass was heated to 70 ⁰ C and continuously in an amount of 90 kg / h by the Inlet 11 is introduced into the device according to the invention. The content of Vorhydrolysesulfatzellstof f in the suspension was chosen so that after evaporation of the excess water, a final cellulose concentration of 10> 1as3en-% was obtained.

The agitator shaft 7 was "operated" at a speed of 450 min, the thickness of the layer spread over the inner wall 1 being 15 mm, and the indirectly heated inner wall 1 had an area of 0.5 m and was treated with heat carrier oil in such a way corresponding to the heating of the suspension (in GegeriiJtrom to the heat carrier oil) resulted in a mean temperature difference VO <83 ⁰ C. the vapor space 15, a pressure of 100 mbar was adjusted.

At the outlet 12, 72 kg of homogeneous cellulose solution could be obtained per hour, which corresponds to a residence time of the suspension in the device according to the invention of 3 minutes. The solution could be discharged in degassed form. Its viscosity was 1500 Pas.see (measured in the relative system). Microscopic examination of the solution revealed that no undissolved cellulose particles were present in the solution.

The resulting vapors were in countercurrent with a

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Withdrawn from 7O ⁰ C and then condensed, the DestiILatst rom per hour 29 kg Bet rug.

Example 2: A suspension of ground prehydrolysulfate ze 11stoff

(Degree of polymerization about 1400) in an aqueous solution of N-methyl-morpholine-N-oxide with a water content of 40 mass% was tempered to 8C ⁿ C and continuously in an amount of 90 kg / h through the inlet 11 in the inventive Institution introduced. The content of

Vorhydrolysesulfat ze 11strff was chosen so that after Evaporate excess water Final cellulose concentration of 15% by mass was obtained.

The stirring shaft 7 was operated at a speed of 450 min "^, wherein the MCKE of the inner wall 1 spreading layer had 1.5 mm. The indir ^r" t heated internal wall 1 had a Fläihe of 0.5 m ^ and was treated with heat transfer oil so that according to the heating of the suspension (in countercurrent to the heat transfer oil), an average temperature difference of 112 ⁰ C. In the vapor space 15, a pressure of 150 mbar ei ngeste lit.

At the outlet 12 64 kg of homogeneous solution could be obtained per hour, which was obtained in degassed form. This mass flow corresponded to a residence time of 4 min.

The solution was obtained as a highly viscous mass (11,000 Pas.see, measured in the relative system), whereby no undissolved Ce I Iu losetei I Chen could be found under the microscope. The solution was fed directly to a spinning machine and spun into cellulose fibers.

The resulting vapors were withdrawn in countercurrent at a temperature of 8O ⁰ C and then condensed, the DestiIlatstrom per hour 26 kg Bet rug.

Claims (8)

claims: 1. A process for the preparation of solutions of cellulose in aqueous tertiary amine oxides from a suspension of cellulose in an aqueous solution of the tertiary amine oxide by heat under reduced pressure, characterized in that the suspension over a heating surface layer or film-like spread, is transported, until a homogeneous solution of cellulose has formed, which has a viscosity between 50 and 15,000 Pas.see, wherein the supply of the suspension and the withdrawal of the homogeneous solution is carried out continuously. 2. The method according to claim 1, characterized in that the spread over the heating surface layer has a maximum thickness of 20 mm, preferably 1.5 to 5 mm. 3, characterized in that the suspension to a temperature between 50 and 15O ⁰ C, preferably between 60 and 100 ⁰ C, brought and a pressure of 0.5 mbar to 1000 mbar, preferably 50 mbar to 150 mbar, is exposed. 3. The method according to claim 1 or 2, characterized in that as tertiary amine N-Methylmorr.ho I i n-N-ox i d, preferably in an aqueous solution with 40% hate% water, is used. 4, characterized in that the transport time during which the suspension is in contact with the heating surface is 1 minute to 60 minutes. - 12 - 4. The method according to one or more of the claims. 1 to 5. The method according to one or more of claims 1 to 6. Device for carrying out the method with an indirectly heated, provided with a stirring device and evacuated vessel, characterized in that the vessel is designed as a cylindrical container (2) with a centrally mounted stirrer shaft (7) and thereto attached stirring blades (8), wherein the radial distance (13) of the stirring blades (8) to the inner wall (1) of the container (2) is a maximum of 20 mm and in the upper part of the container an inlet (11) for the cellulose suspension and in the lower end an outlet (12) for the homogeneous cellulose solution is provided. 7. Device according to claim 6, characterized in that the Ruhr shaft (7) has a distribution ring (10) for layer or film-like propagation of the cellulosic suspension on the inner wall (1) of the container (2). 8. Device according to claim 6 or 7, characterized in that the stirring blades (8) to the axis (9) of the agitator shaft (7) have an inclination angle (alpha), which is adjustable in size.