The present invention relates to the field of batteries, including alkaline (primary and secondary) and lithium batteries, which include separators comprising a porous layer including polymeric fibres.

Such separators serve to prevent an electrical connection between the anode and the cathode of the battery, or a short circuit.

Cellulosic fibres are widely employed in battery separators due to their ability to absorb and retain the electrolytes.

It is, for example, known to employ webs made from pulp or from rayon (viscose) fibres in battery separators.

The use of lyocell fibres in battery separators has been disclosed in EP 0 572 921 Al, US 2007/0014080 Al, US 2010/0310921 and US 2009/0017385 Al. WO 97/37392 discloses a battery separator made from a cellulose film formed from a solution of cellulose in an amine oxide. Further state of the art is provided by US 5,700,700 and DE 198 55 644.

European patent application 1 216 5714.2 (not pre-published) proposes the use of fibres of the lyocell genus with specific R10 and R18-values as well as a specific hemicellulose content in battery separators.

Mercerising cellulosic fibres is well-known in the textile industry for modifying yarns and fabric properties and achieve special performances. In short, mercerising means the treatment of the fibre, yarn or fabric with an alkaline solution, especially NaOH-solution. The effects of mercerisation on the fibre structure of lyocell, modal and viscose fibres have, inter alia, been discussed in Stana-Kleinschek et al., Correlation of regenerated cellulose fibres morphology and surface free energy components, Lenzinger Berichte 82 (2003), 83-95 and Colom, X., Carrillo, F., Crystallinity changes in lyocell and viscose-type fibres by caustic treatment, Europ. Polymer J. 38 (2002), 2225-2230. Mercerisation of fabrics containing lyocell fibre is disclosed in WO 95/024524 Al.

Especially in the case of alkaline batteries, the battery separator is required to have good chemical stability in the presence of strong electrolytes (such as 30-40% KOH). Further details about the requirements of battery separators in various types of batteries are disclosed in e.g. WO 2007/041312.

Furthermore, some of the cellulosic fibres proposed so far to be used in a battery separator (like rayon or mercerized pulp) have poor fibrillation ability and, therefore, do not allow obtaining battery separators with the desired properties in terms of density, porosity and dimensional stability.

It is, therefore, still desired to make battery separators with cellulosic fibres having an enhanced resistance towards alkali solutions.

Accordingly, in one aspect the present invention provides a battery separator, comprising fibres of the lyocell genus, wherein said lyocell fibres are mercerised.

Furthermore, the present invention provides the use of a mercerised lyocell fibre in a battery separator.

The present invention also provides a mercerised lyocell fibre, exhibiting a fibre length of 2- 10 mm.

Finally, the present invention provides a battery, preferably an alkaline battery, comprising the battery separator according to the present invention.

Short description of the drawings

Figures 1 to 4 demonstrate the effect of the mercerisation of lyocell fibres on alkali resistance in terms of RIO-value (Figures 1 and 3) and R18-value (Figures 2 and 4).

Figure 5 shows the results of a Schopper-Riegler test on non-mercerised and mercerised lyocell fibre.

Detailled description of the invention

It has surprisingly been found that mercerised lyocell fibres exhibit a much better resistance to electrolytes of especially alkaline batteries than standard cellulosic fibres hitherto proposed for battery separators. It has been found that mercerised pulp (which is a cellulosic fibre, but not a man-made cellulosic fibre that has been spun from a cellulose-containing solution, like lyocell fibre) exhibits high alkali resistance when used in a battery separator, but exhibits a poor fibrillation ability (cf. US 7,781,104 B2). Apparently, the mercerisation treatment performed on the pulp negatively influences the fibrillation ability of the pulp.

In contrast therto, it has been found that mercerised lyocell fibres not only exhibit high alkali resistance when used in a battery separator, but also high fibrillation ability.

Cellulosic fibres of the lyocell genus are well known for their fibrillation ability and are employed in battery separators. Lyocell fibres are spun from a solution of cellulose in a tertiary amine-oxide.

Thanks to the fine and long fibrils, the separators made with such fibres have a suitable porosity, the ions mobility inside the battery is very good and the efficiency of the battery is high. The fibrils interlace very well during paper making and form a dense structure with low shrinkage and high dimensional stability. Moreover the average size of the pores is small, and this represents a barrier for dendrites.

The RIO-value and the R18-value of the lyocell fibres employed according to the present invention is preferably as follows:

RIO > 87%, preferably > 93%

R18 > 95%, preferably > 98%.

As known to the skilled artisan, the RIO-value of a cellulosic substrate is the amount of undissolved residue when exposing the substrate to 10% NaOH. R18 reflects the amount of undissolved residue when exposing the substrate to 18% NaOH. Both values can be measured according to DIN 54355.

All values given within this application for RIO and R18 are wt.%.

The RIO and R18-values given above are very high. Surprisingly, mercerised lyocell fibres having these properties still not only exhibit high alkali resistance when used in a battery separator, but also high fibrillation ability. When producing battery separators comprising lyocell fibres meeting the above

specifications, it was found that the Reduction by Weight of the separator in 40% KOH was significantly reduced.

Furthermore, separators containing the above- specified fibres have lower Reduction by Area in 40% KOH compared to separators containing other cellulosic fibres.

Lyocell fibres with the above- specified properties have also a high degree of fibrillation when they are refined with the conventional beating systems. For example, the Canadian Standard Freeness (CSF) of the refined fibres is below 700ml, or preferably below 500 ml.

The battery separator according to the present invention may comprise a mixture of mercerised lyocell fibres and, especially a mixture of mercerised lyocell fibres exhibiting the RIO-values and R18-values as set out above.

The amount of the lyocell fibres fulfilling the above requirements in the separator may range from 1% to 100%, preferably 15% or more, 25% or more, 40% or more, or 50% or more.

The separator may comprise other constituents known to the skilled artisan, such as PVA fibres and PVA binders, pulp, non-mercerised viscose fibres or non-mercerised lyocell fibres.

The separator may be of any known design, such as a monolayer or multi-layer design. In multi-layer structures at least one layer should be a nonwoven layer.

In such embodiments, there may be one or more additional layer(s) which can be selected from the group consisting of nonwovens or microporous layers (films), for example cellophane, PVA, polyamide, polyester or polyolefins.

In some embodiments the layers may be glued or thermally bonded together. Each layer may be coated with particles (like inorganic particles), may be grafted, treated with surfactants or corona treated. This kind of treatment may be symmetrical or asymmetrical, as described in US2012/028103A1.

Moreover the separator may include functional substances that have an "ions-trapping" function. They can selectively block molecules that reduce the battery performance

(US2011/0117413A1). It was found that battery separators comprising the lyocell fibres fulfilling the requirements according to the present inventions exhibit advantageous properties, such as

- A Reduction by Weight in KOH of < 3.5%, preferably 2.5% or less

- A Reduction by Area in KOH of < 3.0%, preferably 1.0% or less and/or

- A Frazier Air Permeability of < 50 cm ³ /cm ² /s, preferably 20 cm ³ /cm ² /s, most preferred from 3.5 cm ³ /cm ² /s to 15 cm ³ /cm ² /s.

The lyocell fibres to be employed according to the present invention may exhibit a titre in the range of 0.2-10 dtex, preferably 0.2-2 dtex. The length of the fibres may be in the range of 1-20 mm, preferably 2-10 mm. The diameter of the fibrils after refining the fibres may be between 50 nm and 10.000 nm.

A mercerised lyocell fibre fulfilling the requirements exhibiting a length of from 2 to 10 mm has not been proposed before.

Preferably, the RIO-value and the R18-value of the lyocell fibre according to the present invention is as follows:

R10 > 87%, preferably > 93%

R18 > 95%, preferably > 98%.

The mercerised lyocell fibres employed according to the present invention can be produced by mercerising lyocell fibres according to procedures known to the skilled artisan as such.

Typically, mercerisation is carried out with a NaOH-solution. The concentration of NaOH in the solution may preferably be from 5 wt.% to 20 wt.%. The duration of the treatment (residential time of the fibres in the treatment bath) may preferably be from 120 to 480 seconds.

Mercerisation may be carried out within the fibre production line just before the cutting step, where the fibres are still in the form of continuous filaments called„tow". Alternatively, mercerisation may be carried out in the fibre production line after cutting, when the fibres are already in the form of„staple" or„short cut" fibre. Of course, mercerisation can also be carried out off-line. The mercerisation can be applied to any type of lyocell fibres, independently from the pulp types or other conditions used for the production of the fibres. If as the starting material for mercerisation fibres are used the RIO and R18-values of which are already high, notably RIO > 83%, preferably > 84% and R18 > 93%, preferably > 94%, excellent results can be obtained. The hemicellulose content of such fibres may preferably be <3%, as determined by two step sulphuric acid hydrolysis followed by quantification of the obtained

monosaccharides by anion exchange chromatography.

Fibres with such high RIO and R18-values can be produced by using cellulosic starting materials, especially pulps or pulp mixtures, having corresponding properties in terms of RIO-value, R18-value and hemicellulose content, respectively.

Especially, for making lyocell fibres with such high RIO- and R18-values

- All components of the cellulosic starting material should exhibit

R18>94%,

R10>85% and

Hemicellulose < 3%

- At least 50% in weight of the cellulosic starting material should exhibit

R18>96%,

R10>90% and

Hemicellulose < 3%.

In order to produce lyocell fibres with a very high RIO- and R18-value, at least 50% in weight of the cellulosic starting material should exhibit

R18>98%,

R10>97% and

Hemicellulose< 1 %

Pulps fulfilling the above requirements are commercially available and/or can be produced by the skilled artisan according to the respective needs of the production, see for example US 2009/0312536 Al or WO 2005/118950. The cellulosic starting material may also include cotton linters.

Pulps fulfilling these requirements are commercially available and/or can be produced by the skilled artisan according to the respective needs of the production, see for example

US 2009/0312536 Al or WO 2005/118950.

Examples

Test Methods

Tests on Paper:

Basis Weight

Measured according to ED ANA standard WSP130.1 Thickness

Measured according to ASTM D1777

DensitvCalculated: Density (g/cm ³ ) = ( Basis Weight [g/m ² ] / 10000 ) / (Thickness [μαι] / 10000)

Alkali Proof (Area shrinkage rate in KOH)

Procedure:

cut a square sheet 120mm x 120 mm (Al). Cut carefully the specimen where the paper is uniform.

immerse it in 40% KOH solution at 70°C.

keep in the bath for 8 hours

measure the area of the wet sample (A2)

Area shrinkage rate (%) =(A1-A2)/A1 x 100

Alkali Proof (Weight reduction rate in KOH)

Procedure:

cut one or more pieces of separator with a weight of approximately 5g

dry the sample at 80°C for 1 hour

weigh the dried sample (Wl)

immerse it in 40% KOH solution at 70°C. keep in the bath for 8 hours

wash the sample with water

dry the sample at 80°C for 1 hour

weigh the dried sample (W2)

Weight reduction rate (%) =(W1-W2) W1 x 100

Frazier Air Permeability

Air permeability was measures according to JIS 1096-6,27.

The differential pressure of the air flow passing through the material was 0,5 inches of water. Porosity

It was calculated dividing the paper basis weight (g/m ² ) by the polymer density (g/cm ³ ) and by the paper thickness (μιη), multiplying by 100 and finally subtracting the result by 100. Porosity ( )= 100 - (basis weight / [density x thickness] x 100)

Manufacture of lyocell fibres

Lyocell fibres were manufactured according to methods known as such to the skilled artisan from different pulps. The properties of the pulps employed, their respective amount in the fibre produced therefrom, and the properties of the resulting fibres are listed in the following table:

Table 1:

Mercerisation of Fibres Lyocell fibres produced from the same starting materials and spun under the same conditions as for examples B and C above were mercerised in aqueous NaOH- solutions in the tow form. The fibres were then cut to a length of 3 mm. The mercerisation process employed the following parameters:

Concentration of NaOH (%): 5 - 10 - 15 - 20

Residential time (s): 120 - 240 - 480

Bath temperature (°C): 25

The alkali resistances of the mercerised fibres in terms of RlO-value and R18-value were determined.

The respective test regimes and results in terms of RlO-value and R18-value are summarized in the following table:

Table 2 - Test Regimes for mercerisation and results

Mercerisation conditions Alkali Resistance

NaOH Bath

Residential

example concentration Temperature,

time (s) R10% R18%

Starting fibers ( ) °C

C-1-0 Example C 0 0 25 85.7 95.2

C-l-1 Example C 5 120 25 87.0 97.0

C-l-2 Example C 10 120 25 91.3 98.4

C-l-3 Example C 15 120 25 94.5 98.9

C-l-4 Example C 20 120 25 94.5 98.7

C-2-4 Example C 5 240 25 87.0 96.9

C-3-1 Example C 10 240 25 93.5 98.6

C-2-6 Example C 15 240 25 96.5 99.3

C-3-2 Example C 20 240 25 96.8 98.5

C-3-3 Example C 5 480 25 87.0 96.9

C-3-4 Example C 10 480 25 95.3 98.6

C-3-5 Example C 15 480 25 96.7 98.7

C-3-6 Example C 20 480 25 96.9 98.6

B-4-0 Example B 0 0 25 82.4 92.3

B-4-1 Example B 5 240 25 83.3 95.0

B-4-2 Example B 10 240 25 93.4 97.2

B-4-3 Example B 15 240 25 95.4 97.7

B-4-4 Example B 20 240 25 94.8 97.9 The results are shown graphically in Figure 1 (RIO-value) and Figure 2 (R18-value) concerning the fibre of Example C, and Figure 3 (RIO-value) and Figure 4 (R18-value concerning the fibre of Example B.

One can see that the RlO-values and R18-values of lyocell fibres are significantly enhanced by a mercerisation treatment.

Refining

Lyocell fibres were refined with a Valley Beater according to ISO 5264-1.

Pulp fibres were refined with a PFI U3000 mill according to ISO 5264-2.

A Schopper-Riegler-test was performed on the unmercerised fibre of Example B and the mercerised fibre according to Example B-4-3 above in a Valley Beater.

The results of the tests are shown in Figure 3. One can clearly see that the mercerised fibre develops higher Schopper-Riegler-values within a shorter refining time This means that the mercerised lyocell fibre has a high degree of fibrillation.

Paper samples

Paper samples were prepared with a RAPID-KOTHEN sheet former, according to EN ISO 5269/2.

Various papers were manufactured from the fibres as summarized above, optionally in a mixture with other constituents.

Further tests were made with papers employing non-mercerised lyocell fibres, as well as with papers containing other constituents.

The composition of the paper samples as well as the properties determined therein are summarized in the following tables: Table 3- Examples according to the invention

Table 4 - Comparison Examples

Comparing Comparison Example 15 with Inventive Examples 13 and 14 and Comparison Example 16 with Inventive Examples 8 to 12, respectively, there is a remarkable reduction in the Weight Reduction rate in KOH obtained by employing mercerised lyocell fibre instead of non-mercerised lyocell fibre.