T 0498/98 03-04-2001

1. The appeal is admissible.

Main request

2. Amendments

2.1. Claim 1 of the main request differs from Claim 1 as originally filed by (a) the fact that it is directed to a magnetic tape obtained by forming a magnetic recording layer on one surface of a biaxially oriented long polyethylene-2,6-naphthalate film having a thickness of 2 to 12 m and by (b) the indication that the average particle diameter of the second inert solid particles is greater than the average particle diameter of the first inert solid particles by at least 0.25 m.

2.2. Amendment (a) finds adequate support in originally filed Claims 4 and 5 and is therefore allowable under Article 123(2) EPC.

2.3. Concerning amendment (b)

2.3.1. As indicated in the application documents as originally filed (cf. page 4, lines 26 to 30 of the description), the average particle diameter of the second inert solid particles is greater than the average particle diameter of the first inert solid particles by at least 0,2 m, preferably 0.3 m.

2.3.2. The only reference in the application documents as filed to a difference between the average diameters of the second and the first solid inert particles of 0.25. m is to be found in Example 3. In this example 0.015% by weight of particles of calcium carbonate having an average particle diameter of 0.5 m and 0.3% of a monodisperse silica having an average particle diameter of 0.25 m are incorporated in the PEN film. The use of this specific filler combination leads to a polyester film having specific roughness (0.008 m), Young's moduli (800 and 750 kg/mm2) and heat shrinkage (0.05%).

2.3.3. As stated in the decision T 201/83 (OJ EPO 1984, 481) an amendment of a range in a claim is allowable on the basis of a particular value described in a specific example, provided the skilled person could have readily recognised this value as not so closely associated with the other features of the example to determine the effect of that embodiment of the invention as a whole in an unique manner and to a significant degree.

2.3.4. In the present case the roughness of the film obtained in this example is clearly dependent on the amount, the average diameter and the difference in average diameters of the solid inert particles. Furthermore, as put forward by the Appellant, the parameters thermal shrinkage, Young's moduli and roughness which are used in combination to characterize the PEN film used in the claimed magnetic tapes are mutually dependent, so that the difference in the average diameters of the solid inert particles disclosed in Example 3 is closely associated with the specific values of these parameters in this example. Thus, the conditions set out in the decision T 201/83 are not met in the present case.

2.3.5. The argument of the Appellant that this difference (i.e. 0.25 m) in the average diameters of the two kinds of inert solid particles was disclosed in view of the difference between the lower limit of the average diameter range of the second inert solid particles, and the lower limit of the average diameter range of the first inert solid particles is not pertinent, since there is no support in the application as filed for a general rule or principle establishing a constant such difference between the particle diameters of the first and second inert solid particles respectively (cf. section 2.3.1 above). Nor is there any support for a specific combination of first solid inert particles having an average diameter of 0.05 m and second solid inert particles having an average diameter of 0.3 m. On the contrary, Example 3 merely refers to first solid particles having an average diameter of 0.25. m and to second solid particles having an average diameter of 0.5 m i.e. in both cases well above the lower limits set out for the average diameters of the solid particles.

2.3.6. It follows that the amendment (b) cannot be considered as meeting the requirements of Article 123(2) EPC. Therefore, the main request is not allowable.

First auxiliary request

3. Amendments

3.1. Claim 1 of the first auxiliary request differs from Claim 1 as originally filed by (a) the fact that it is directed to a magnetic tape obtained by forming a magnetic recording layer on one surface of a biaxially oriented long polyethylene-2,6-naphthalate film having a thickness of 2 to 12 m and (b) the indication that the average particle diameter of the second inert solid particles is greater than the average particle diameter of the first inert solid particles by at least 0.3 m.

3.2. As indicated above in paragraph 2.1, amendment (a) is fully supported by the application documents as originally filed.

3.3. Amendment (b) finds its support at page 4, lines 26 to 30. of the description as originally filed.

3.4. Claims 2 to 3 of this request are appendant to Claim 1 and further define features which respectively correspond to those in original Claims 2 to 3.

3.5. Thus, the first auxiliary request is allowable under the provisions of Article 123(2) EPC.

4. Clarity and support

4.1. In view of the disclosure of the application in suit which gives details as to how to determine the heat shrinkage value, the Young's moduli and the roughness of the films (cf. page 11, line 21 to page 12, line 20), the Board takes the view that these parameters are appropriately defined so that the requirements of Article 84 EPC are considered to be fulfilled. Having regard to the length of the description of each method used for the determination of these parameters, their inclusion in Claim 1 does not appear appropriate, since this would make this claim unclear through lack of conciseness.

4.2. The fact that the two kinds of solid inert particles might be of the same chemical nature, does not lead to a lack of clarity, since, being characterized by their average particle diameter and difference thereof (i.e. at least 0.3 m), they will also exhibit two different particle size distributions allowing them to be distinguished from each other.

4.3. Thus, the Board is satisfied that Claims 1 to 3 meet the requirements of Article 84 EPC.

5. Novelty

5.1. Documents

The following documents have been considered during the examining procedure:

D1: JP-A-2214736 (in form of the abstract Nr 90-302374 from the WPIL Derwent Database),

D2: JP-A-61179721 (in form of the abstract Nr 86-250145 from the WPIL Derwent Database),

D3: EP-A-0 257 611, and

D4: EP-A-0 124 291.

5.1.1. D1 relates to biaxially oriented polyester (e.g. polyester resins comprising ethylene-2,6-naphthalate units) films containing two kinds of granules in different concentration in different zones, used as base for magnetic tapes. These films contain 0.1 to 2 wt% of granules (A) having an average granular diameter of 5 to 300 nm and 0.005 wt% of granules (B) having an average granular diameter of 300 to 2000 nm, the zones in vicinity of the granules (B) having a higher concentration of granules (A) than other zones. Alumina and titanium nitrile are preferably used as granules (A) silica and calcium carbonate being preferred as granules (B).

5.1.2. D2 is directed to oriented polyester (e.g. polyalkylene naphthalate) films useful as base for magnetic recording material. These films contain 0.01 to 0.5 wt% of one particle having an average size of 0.01 to 0.2 m selected from silica and titanium dioxide and 0.01 to 0.3 wt% of calcium carbonate having an average particle size of 0.1 to 0.5 m.

5.1.3. D3 refers to a polyester composition comprising a polyester and 0.001 to 5% by weight of fine spherical silica particles (A) obtained by subjecting alkoxysilanes to hydrolysis and condensation reaction, said particles being substantially amorphous and having an average diameter D1 of 0.01 to 3 m and a diameter dispersion index d10/d90 in the range of 1.1 to 2.7. This polyester composition may also comprise in addition to the particles (A) fine particles B-1 in an amount of 0.005. to 1 % by weight, the average diameter D2 of the particles B-1 being such that D2/D1 is in the range from 1.1. to 3, and the weight ratio of B-1 particles to (A) particles being preferably in the range 0.01 to 0.1. Polyethylene-2,6-naphthalate is one of the preferred polyesters used in these compositions. These compositions are used in the manufacture of biaxially oriented films having a thickness of 4 to 30 m, useful as support for magnetic tapes. The roughness of the films is in the range from 3 nm to 15 nm. In the case of a film made with PEN, the F5 value (i.e. stress at 5% elongation) in the machine direction is preferably greater than 20 kg/mm2 and is related to the F5 value in the transverse direction by the formula 3 > F 5MD /F 5TD > 1.1. The heat shrinkage of the films should be low in order not to deteriorate the skew properties of the magnetic recording medium (cf. D3, Claims 1, 10, 17; page 4, lines 21 to 34; page 6, lines 37 to 41; page 6, line 53 to page 7, line 10; page 9, lines 33 to 50; page 10, lines 36 to 40; page 11, lines 1 to 3). In its Example G4 D3 discloses a PEN film having a thickness of 7 m, a roughness of 8 nm, exhibiting a F5MD value of 29. kg/mm2, and containing 0.3 wt% of a spherical silica having an average particle diameter of 0.27 µm but gives no information on the particle diameter dispersion of the spherical silica used, the heat shrinkage and the F5TD of this film.

5.1.4. D4 discloses biaxially oriented aromatic polyester films having a thickness of 3 to 100 m, exhibiting a surface roughness from 0.001 to 0.016 m and comprising anatase titanium dioxide particles or a combination thereof with calcium carbonate particles. In the latter case 0.1 to 0,5 % by weight of anatase particles having an average particle diameter in the range of 0.1 to 0.5 m are combined with 0.1 to 0.3% by weight of calcium carbonate particles of an average particle diameter of 0.3. to 1,5 m. Preferred polyester resins are polyethylene terephthalate and polyethylene naphthalate. Due to their excellent flatness and slipperiness, these films are suitable as base for magnetic tapes (cf. D4, Claim 1; page 4, line 30 to page 5, line 4; page 8, lines 2 to 3; page 11, lines 6 to 11; page 12, lines 10 to 15; page 13, lines 3 to 12; page 15, lines 20 to 22). In its Example 7 D4 discloses a film based on PEN. This film comprises anatase particles having an average diameter of 0.1 m in an amount of 0.15% by weight and has a roughness of 7 nm, but there is no mention of the thickness, the heat shrinkage and the Young's moduli of the film.

5.2. Thus, none of the documents D1 to D4 discloses a magnetic tape obtained by forming a magnetic recording layer on one surface of a biaxially oriented unidirectionally long PEN film having a thickness of 2 to 12 m and exhibiting the combination of the characteristics A(a), (A(b), (B), (C), and (D) as required in Claim 1 of the first auxiliary request. The subject-matter of Claim 1 of this request meets therefore the requirements of Article 54 EPC.

6. Inventive step

6.1. The patent application in suit relates to magnetic tapes having as base film a biaxially oriented PEN film.

6.2. Whilst there is a conspicuous absence of any reference to a specifically identified relevant prior art document in the introductory description of the application in suit, such tapes are described in documents D1 to D4.

6.3. The wording of present Claim 1 reveals that the thickness of the PEN film and the features A(a), A(b), B, C, and D are essential in the definition of the biaxially oriented PEN film used as base for the claimed magnetic tapes.

6.4. Example G4 of D3 discloses a PEN film having a thickness of 7 µm and meeting the requirements A(a) and D set out for the biaxially oriented PEN films according to the present application. Furthermore, as shown by the experimental report submitted by the Appellant with his letter of 2 March 2001, the Young's modulus in the length direction of this film is clearly above 650 kg/mm2 and greater than the Young's modulus in the width direction (i.e. 560 kg/mm2). Thus, the films used as support for the magnetic tapes according to the present application are distinguished from the film disclosed in Example G4 of D3 only in that they contain 0.005. to 0.5 by weight of second inert particles having an average particle diameter 0.3 to 1.0 m, this average particle diameter being greater than the average particle diameter of the first inert solid particles by at least 0.3 m, by a Young's modulus in the width direction of at least 600 kg/mm2 and by a heat shrinkage factor in the length direction after heat treatment at 70 C for 1 hour under no load of not more than 0.08%.

Therefore, Example G4 of D3 is considered as the closest prior art.

6.5. Starting from Example G4 of D3 the technical problem underlying the present application may be seen in the provision of further magnetic tapes having biaxially oriented PEN film as support and exhibiting excellent electromagnetic characteristics, running durability, skew properties and enabling a long term high density recording.

6.6. In view of the experimental results in the Examples 1, 2, and 4 the Board considers that the above defined problem is effectively solved by the combination of features according to Claim 1.

7. Obviousness

It remains to be decided whether the claimed subject-matter is obvious having regard to the documents on file.

7.1. The aim of D3 is to provide polyester films, which can be used as support for magnetic tapes exhibiting good electromagnetic and running properties. According to D3, and as submitted by the Appellant, the essential technical feature to solve this problem is related to the use of very specific amorphous spherical silica particles as filler in the polyester film (cf. D3, page 3, lines 45 to 52; page 11, lines 39 to 41).

7.2. D3 also teaches that other types of inactive particles may be combined with the fine spherical silica particles in the polyester compositions used in the manufacture of biaxially oriented polyester films. As indicated in D3 the ratio of the diameter of the second particles (B-1 particles) to the diameter of the spherical silica particles should be in the range 1.1 to 3 and the amount of these second particles should be at least 0.005% by weight and in a ratio from preferably 0.01 to 0.1 in respect of the amount of the silica particles. D3 stresses the influence of this diameter ratio (i.e. a relative value) on the running properties of the tapes but does not teach a minimum absolute value for the difference between the average particle diameters of the two types of solid particles (cf. page 6, line 7 to page 7, line 4).

7.3. D3 does not expressis verbis mention the Young's moduli of the films but discloses the importance of the F5 values in the machine and transverse directions, these values being related to the Young's moduli of the film (i.e. and as submitted by the Appellant the Young's moduli being generally at least 20 times greater than the respective F5 values) and being dependent on the stretching conditions applied during the manufacture of the film (cf. page 9, line 36 to page 10, line 19). The F5 value in the machine direction should be greater than 20. kg/mm2 and linked to the F5 value in the transverse direction by the formula 3 > F5MD /F5TD > 1.1. Nevertheless, even if it could be assumed that such a relationship would also exist between the corresponding Young's moduli, no indication can be found in D3 as to whether the Young's modulus in the width direction should be at least 600 kg/mm2 in order to obtain tapes with good running and electromagnetic properties.

7.4. The influence of the heat shrinkage of the films on the skew properties of the magnetic tapes obtained therefrom is also taught in D3 (cf, page 10, lines 37 to 40) but D3 does not mention specific values for this property. D3 also indicates that the roughness of the films should be between 3 and 15 nm in order to obtain good reproduction output as a high density recording medium and that the roughness is dependent on the average diameter of the particles used and the amount thereof and on the stretching conditions applied in the manufacture of the film (cf. page 11, lines 1 to 10).

7.5. Thus, if the skilled person starting from Example G4 of D3 would have followed the teaching of D3, he could have added second particles having an average diameter between 0.297 m and 0.81 m in an amount between 0.005% to 0.03 by weight in order to obtain a film having a roughness of up to 15 nm, but he would not have recognized the critical effects of the values of the heat shrinkage (cf. comparative Example 4), of the Young's modulus in the width direction (cf. comparative Example 6) and of the roughness (cf. comparative Example 7) as set out in present Claim 1 on the running and electromagnetic properties of the magnetic tapes obtained therefrom, and the fact that, the roughness, the shrinkage and the Young's moduli of the film being mutually dependent, only a specific combination of inert particles (in particular having a specific difference in average particle diameters) as set out in present Claim 1 could allow the manufacture of films exhibiting this critical and unique combination of properties.

7.6. Thus, D3 itself will not lead to magnetic tapes having as support a biaxially oriented PEN film exhibiting the combination of features as required in present Claim 1 and cannot render the subject-matter of this claim obvious.

7.7. The same argument is also valid for D4, which relates to biaxially oriented polyester films containing two kinds of inert particles and useful as support for magnetic tapes, but gives no indication in order to use a combination of inert solid particles according to present Claim 1 for obtaining magnetic tapes having as support a PEN film exhibiting the unique and critical combination of heat shrinkage, Young's moduli and roughness as required in this claim.

7.8. D1 and D2 do not contain any information concerning the Young's moduli of the films in both directions, the difference in the average particle diameter between the first and the second solid particles and the heat shrinkage of the film and the influence of these features on the properties of the magnetic tapes obtained therefrom. Thus, D1 and D2 do not add anything to the information already present in D3.

7.9. Consequently, the solution of the technical problem does not arise in an obvious way from the cited prior art. It follows that the subject-matter of Claim 1 meets the requirements of Article 56 EPC.

8. Dependent Claims 2 and 3, which relate to preferred features of the film used as support for the magnetic tape set forth in Claim 1, are supported by the patentability of this claim and are therefore also allowable. Since the first auxiliary request is allowable, there is no need for the Board to consider the second and the third auxiliary requests.