Method for the production of cellulosic flat films
The present invention relates to the production of cellulosic flat films via the so-called amine-oxide process.
In this process a solution of cellulose in an aqueous tertiary amine oxide is shaped into the form of a film by means of an extrusion die with an elongated extrusion gap. The shaped solution is transported into a precipitation bath via an air gap. In the precipitation bath the coagulation of the cellulose takes place and the cellulosic flat film is formed.
The cellulosic flat film thus produced is washed and dried. Known processes for the production of cellulosic flat films via the amine-oxide process are disclosed for example in PCT-WO 98/49223, PCT-WO 98/49224 and PCT-WO 99/21700. Cellulosic films produced via the amine-oxide process may be used for a variety of applications, including membrane applications as disclosed in EP 0 807 460, in a battery separator as disclosed in PCT-WO 97/37392 or in tubular food casings as for example disclosed in US-A 5,658,524.
From PCT-WO 98/49224 an improved process is known, wherein the cellulosic flat film is stretched in the transversal direction after having entered the precipitation bath. By stretching the cellulosic flat film in the transversal direction after having entered the precipitation bath, the mechanical properties of the film can be improved. Furthermore, the usefulness of the film as a membrane in separation processes is enhanced.
According to PCT-WO 98/49224, stretching in the transversal direction is preferably performed after the washing step and before the drying step. One typical process includes the steps of stretching the washed film in the transversal direction in a continuously operating stenter frame and then drying the stretched film in a contact dryer.
However, it has now been observed that the tenacity in transversal direction (TD) of the thus obtained transversally stretched films is still less than desired. This seems to be a result of a certain shrinkage of the film occuring in transversal direction in the steps following transversally stretching, especially the drying step. This leads to a loss in width and transversal orientation of the film.
For the purposes of the present specification, if negative values for the dimensional stability of a films are given, this means that shrinkage in transversal and/or longitudinal direction occurs.
It is, therefore, an object of the present invention to provide a process of the above described kind, wherein shrinkage of the film in transversal direction in the steps following stretching in transversal direction can be reduced or avoided. Furthermore, it is an object of the present invention to provide cellulosic flat films produced via the amine-oxide process with better mechanical properties and better suitability for the use as a membrane in separation processes or in a battery separator. It is a further object of the present invention to provide cellulosic flat films with a very low thickness, such as less than 10 μm, and exhibiting balanced properties in regard to MD (machine direction) and TD tenacity.
The method according to the invention, comprising the steps of
- shaping a solution of cellulose in an aqueous tertiary amine oxide into the form of a film by means of an extrusion die with an elongated extrusion gap,
- transporting the shaped solution via an air gap into a precipitation bath, whereupon the cellulosic flat film is formed in said precipitation bath,
- stretching the cellulosic flat film in the transversal direction after having entered the precipitation bath,
- washing the cellulosic flat film and
- drying the cellulosic flat film,
is characterized in that the transversally stretched cellulosic flat film is during the steps following the transversal stretching at least partly exposed to a transversal tension sufficient to substantially prevent transversal shrinkage.
Preferably the cellulosic flat film is dried while being exposed to transversal tension to a moisture content of less than 200%, more preferred less than 100%, and especially preferred less than 50% (w/w based on weight of cellulose). The film can also be dried completely while being exposed to said transversal tension.
Surprisingly, it has been found that if the transversally stretched cellulosic flat film is at least partly exposed to transversal tension, especially during the drying step, shrinkage in transversal direction can be significantly reduced in comparison with hitherto known
processes. Furthermore, TD tenacity of the films can thereby be significantly increased without substantially influencing MD tenacity.
For one skilled in the art it is easily possible to determine the degree of transversal tension necessary to substantially prevent the transversal shrinkage of the film. Such transversal tension can for example be applied by fastening the film at its edges and thereby keeping the film at its original width.
By determining whether transversal tension is to be applied throughout the steps following the transversal stretching, for example throughout a drying step, or only partly during said steps, i.e. during drying only until a specific degree of moisture is achieved, one can easily influence and control the total degree of transversal shrinkage and also the relation between tenacity in MD and TD directions of the finally obtained film.
One especially preferred embodiment of the present invention is characterized in that the cellulosic flat film is at least partly dried whilst being stretched in the transversal direction. Thereby the steps of transversal stretching and drying are at least jpartly combined.
The cellulosic flat film is stretched in the transversal direction preferably after the film has left the precipitation bath and has been washed. Especially when the drying of the film is carried out at least partly during the step of transversally stretching the film, it is preferred to stretch the film after having left the precipitation bath and having been washed. However, it is to be understood that stretching in transversal direction may also be performed at other stages of the process, e.g. before washing.
The cellulosic flat film may also be first dried and then re-wettened and stretched in transversal direction whilst again being dried at least partly.
Preferably, residual moisture in the cellulosic flat film is removed after the film has been stretched in the transversal direction.
One embodiment of the present invention comprises the steps of stretching the film in transversal direction in a continuously operating stenter frame and drying the film at least partly in said stenter frame while and/or after being stretched. I.e., the film may first be stretched in transversal direction in the stenter frame and is then kept in the stenter frame under transversal tension in order to prevent transversal shrinkage while being at least partly dried.
Residual moisture (if there is any) of the film leaving the stenter frame is then removed in a further dryer, for example a contact dryer.
Drying the film while being exposed to transversal tension may be performed in one step or in several steps and may be accomplished in one single apparatus or several apparatuses capable of drying films.
In a further preferred embodiment of the present invention stretching in the transversal direction is performed in two steps, wherein in the first step the flat film is stretched to a stretching degree being higher than the stretching degree finally desired, and in the second step the flat film is allowed to relax to the stretching degree finally desired.
I.e., given a finally desired stretching degree such as 200%, the film is in a first step stretched up to a degree higher than the degree finally desired, such as for example 300%, and is then in a second step allowed to relax to the desired stretching degree of 200%. For the purposes of the present invention the percentages given for the stretching degree are based on the width of the unstretched film. Therefore, a stretching degree of for example 200%) means that the stretched film has a width of 3 times the width of the unstretched film (100% + 200%).
It has surprisingly been shown that with this preferred embodiment of the present invention the dimensional stability of thus produced flat films in liquids such as water or aqueous alkali can be significantly improved, thus making the films even more suitable for applications such as a membrane in a separation process or especially in a battery separator.
Preferably in the second step of stretching, the flat film is allowed to relax continuously. The flat film may also be allowed to relax stepwise in the second step of stretching.
Relaxation of the film is preferably carried out in a controlled manner, i.e. the film is kept under a certain transversal tension whilst being allowed to relax. This can for example be accomplished by continuing to hold the film at its edges in a stenter frame.
In the first step of transversal stretching the flat film is preferably stretched to a stretching degree being at least 50%) higher, more preferred at least 100% higher than the stretching degree finally desired.
The final stretching degree of the cellulosic flat film may be 350%.
Transversal stretching of the cellulosic flat film is preferably performed in a continuously operating stenter frame.
Preferably the shaped solution is stretched in the longitudinal direction whilst being transported through the air gap.
The cellulosic flat film may be treated with a softener, preferably after washing. It is also possible to incorporate softeners into the extrusion solution, which are resistant to the chemical and physical conditions of the extrusion solution and the precipitation bath.
As the tertiary amine oxide, N-methyl-morpholine-N-oxide (NMMO) is preferably used.
The present invention furthermore encompasses a cellulosic flat film which is obtainable by the method according to the present invention.
The cellulosic flat films according to the invention are especially characterized by having a thickness d of 15 μm or less and exhibiting a factor f of 40 or less, preferably 35 or less, wherein f is defined as f = d * (MD/TD), wherein d is inserted in μm and wherein MD is the tenacity of the film in machine direction (N/mm2) and TD is the tenacity of the film in transversal direction (N/mm2). Preferably, the cellulosic flat films have a thickness d of
10 μm or less.
From PCT-WO 00/24812 cellulosic flat films with a thickness d of less than 20 μm and exhibiting a factor f of 65 or less are known. However, according to PCT-WO 00/24812 a film having a thickness of only 9 μm exhibits a factor f of 65 and films with thicknesses of
11 and 13μm exhibit factors f of 45 and 46, respectively. With the present invention it is now possible to provide very thin films with yet more balanced MD/TD tenacity properties, rendering such films competitive against comparable synthetic films.
Cellulosic flat films obtainable by the two-step stretching as described above are " characterized by a dimensional stability in transversal direction with a value of greater than -10%) when exposed to water (as measured according to the test method described below in regard to the examples).
Furthermore, cellulosic flat films obtainable by the two-step stretching as described above are characterized by a dimensional stability in transversal direction with a value of greater
than -15 % when exposed to 40% KOH (as measured according to the test method described below in regard to the examples).
I.e., the films according to the invention only show very small shrinkage when exposed to water or aqueous alkali.
In some cases even an expansion of the films according to the invention when exposed to water and/or aqueous alkaline solutions has been observed, i.e. the values for the dimensional stability are positive.
It can be shown that the dimensional stability of the films according to the invention when exposed to water and/or aqueous alkaline solutions tends to be even greater when the degree of transversal stretching of the film during its production process is held at a comparatively lower level such as lower than 100 %. This means that one skilled in the art by controlling the parameters of transversal stretching, relaxation, and preventing shrinkage after transversal stretching can adjust the properties of the obtained film within a wide variety ranging from films with lower TD tenacity but well suited for use e.g. as a battery separator in aqueous and/or alkaline media up to thin films with very high and balanced MD and TD tenacities.
The present invention furthermore relates to the use of a cellulosic flat film according to the invention as a packaging film, agricultural film, diaper film, office film, household film, in battery separators and/or as a membrane.
Examples
Example 1
A solution of cellulose in NMMO (13 % w/w cellulose) which was prepared by methods known in the art was extruded through a flat film die having an extrusion gap length of 40 cm and an extrusion gap width of 300 μm. The shaped solution whilst being stretched in the longitudinal direction at a stretch ratio of 3.2:1 was transported through an air gap into a precipitation bath where coagulation of the cellulose and formation of the cellulosic flat film occurred. After washing out the NMMO of the formed film, the film was stretched to a stretching degree of 150% in a continuous stretching apparatus.
In the stretching apparatus the film was in a comparison example not dried while being transversally stretched and in the examples according to the present invention at least partly dried.
After leaving the stretching apparatus the film was finally dried in a frame, whereby the film is allowed to shrink in transverse direction under a load of 50 g/cm.
The moisture content of the film when leaving the stretching apparatus was determined. Furthermore, the total shrinkage of the film in transversal direction after stretching and drying was calculated.
Tenacities of the produced films in machine direction (MD) and in transversal direction (TD) were measured with a Materials Tester Type Z 2.5/TN IP (obtainable from company Zwick; crosshead speed 100 mm/min, sample width 15 mm, determination of sample thickness with a Schroder Micrometer) and the relationship between MD and TD tenacities was calculated.
Table 1 contains the data obtained from the above described experiments:
Table 1
As can be seen from example 1.1, which is a comparison example, the flat film which has not been exposed to transversal tension while being dried exhibits significant total shrinkage in transverse direction.
Furthermore, it can be seen from examples 1.2 to 1.7 where the film was dried to different moisture contents while being stretched transversally, that total shrinkage can be significantly reduced or even totally avoided (cf. example 1.7, where the film was nearly completely dried whilst being transversally stretched). Furthermore, it is observed that TD tenacity of the thus produced films is improved while MD tenacity is not influenced significantly.
Example 2:
A cellulosic flat film was produced wherein the parameters of extrusion, longitudinally stretching in the air gap, precipitation and washing were the same as in example 1.
The washed film was stretched in transversal direction in a continuously working stretching apparatus, the stretching degree finally desired being 150 %.
In the stretching apparatus, the film was in accordance with the present invention first stretched to a stretching degree being higher than the stretching degree finally desired and was afterwards allowed to relax in a controlled manner to the stretching degree finally desired, with the film being kept under tension in the stretching apparatus. The film was then dried while being kept under tension at a stretching degree of 150 %.
In a comparison example, the film was stretched to the stretching degree finally desired in one step.
The dimensional stability of the thus produced films when exposed to H O and 40% KOH was measured as follows:
Depending on the width of the film 5 to 6 samples having a dimension of 20 x 30 mm were punched out of the film at locations equally distributed over the width of the film. The exact dimension of the samples in TD direction was determined by measuring with a microscope/image analysis.
The samples were placed in a beaker with deionized water or 40% KOH, respectively, at room temperature such that the samples were totally immersed in the liquid. The samples were left immersed in the liquid for 30 minutes in the case of water and for 1 hour in the case of 40% KOH.
After removing the samples from the liquid the dimension in TD direction was measured again as described above.
Dimensional Stability of the samples is calculated according to the following formula:
Dimensional Stability (%) = ^ ~ ^ *100,
where Lj is the initial length (TD direction) before immersion and L is the corresponding length (TD direction) after immersion in the test liquid. Then the mean average of the values obtained is calculated.
In this regard it is to be noted that in the case of films having been dried in a cylinder dryer (where free relaxation at the edges of the film takes place), samples taken from the edges of the film should not be included in the calculation of the mean average.
The results of the experiments are shown in Table 2:
Table 2
As can be seen from table 2, transverse shrinkage of the films when exposed to H2O or KOH can be significantly reduced when the films are stretched according to the present invention (examples 2.2 and 2.3) as compared with comparison example 2.1.
Example 3 :
A solution of cellulose in NMMO (13 % w/w cellulose) which was prepared by methods known in the art was extruded through a flat film die having an extrusion gap length of 100 cm and an extrusion gap width of 250 μm. The shaped solution whilst being stretched in
the longitudinal direction at a stretch ratio of 2.5:1 was transported through an air gap into a precipitation bath where coagulation of the cellulose and formation of the cellulosic flat film occurred. After washing out the NMMO of the formed film, the film was stretched in transversal direction to a stretching degree of 155% in a continuous stretching apparatus, partially dried in this continuous stretching apparatus to a moisture of 50%) (on cellulose) while being exposed to transversal tension and afterwards allowed to relax to a final stretching degree of 39% during drying in a cylinder dryer.
The results of this experiment are shown in Table 3:
Table 3
Example 4:
A solution of cellulose in NMMO (13 % w/w cellulose) which was prepared by methods known in the art was extruded through a flat film die having an extrusion gap length of 100 cm and an extrusion gap width of 100 μm. The shaped solution whilst being stretched in the longitudinal direction at a stretch ratio of 1.3:1 was transported through an air gap into a precipitation bath where coagulation of the cellulose and formation of the cellulosic flat film occurred. After washing out the NMMO of the formed film, the film was stretched in transversal direction to a stretching degree of 135%) in a continuous stretching apparatus, partially dried in this continuous stretching apparatus to a moisture of 50%> (on cellulose) while being exposed to transversal tension and afterwards allowed to relax to a final stretching degree of 35 > during drying in a cylinder dryer.
The results of this experiment are shown in Table 4:
Table 4