T 0973/98 24-09-2002

1. The appeal is admissible.

2. Amendments

2.1. Article 123(2) EPC

2.1.1. Claim 1 arises from the combination of claims 1 to 6 as granted and the addition of the following features:

"complex oxide", "a is 1", "n is from 80% to 97% of (3a + 2.5b + 3c + 2.5x)" and "at a temperature of from 400°C to 650°C".

2.1.2. Claims 1 to 6 as granted are identical to claims 1 to 6 as originally filed. Claims 2 to 6 contain a reference to claim 1.

2.1.3. The term "complex oxide" is present in granted claims 7 and 8, which correspond to original claims 7 and 8, all of them referring to claims 1 to 4. Thus, in this respect, claim 1 concerns a specific object which as such had already been claimed both in the patent as granted as well as in the original application.

2.1.4. As regards the feature "a is 1", which refers to the coefficient of molybdenum (Mo), the amendment, which in fact amounts to a different way of indicating the same formula, has a basis on original page 6, line 20 (wherein "a" is the coefficient of Mo) as well as on page 7, line 9 (wherein "a is 1" is disclosed for formula (1)) of the application as originally filed.

2.1.5. The formula "n is from 80% to 97% of (3a + 2.5b + 3c + 2.5x)" was disclosed in the original application, on page 6, lines 20 to 21.

2.1.6. The amendment "at a temperature of from 400°C to 650°C", to indicate the temperature range at which the calcination mentioned in claim 1 is carried out, has a basis in original claim 6, as far as the combination of calcination and temperature range is concerned, and on original page 6, line 10, as far as the preferred temperature range is concerned.

2.1.7. The absence of the feature "specific crystal structure" in claim 1 according to the main request submitted during the oral proceedings does not contravene the requirements of Article 123(2) EPC, since that feature was not present in the original claims.

2.1.8. Therefore, the patent has not been amended in such a way that it contains subject-matter which extends beyond the content of the application as filed (Article 123(2) EPC).

2.2. Article 123(3) EPC

2.2.1. The absence of the feature "specific crystal structure" in claim 1 according to the main request does not contravene the requirements of Article 123(3) EPC, since that feature was not present in the granted claims.

2.2.2. The further amendments to the claims in fact restrict their scope.

2.3. Article 84 EPC

2.3.1. The respondent argued that the term "complex oxide" arose from a modification of the claims by a term taken from the description, so that its clarity should be examined. However, present claim 1, in this respect, results from the combination of granted claims 1 to 6, with the further restriction "complex oxide" taken from claim 7 or 8 (see point 2.1.3, supra). Therefore, an objection of lack of clarity in view of the term "complex oxide" is not allowable, as established eg in T 367/96 of 3 December 1997, point 2 of the catchwords (cited in Case Law of the Boards of Appeal of the EPO, 4th edition 2001, VII.C.10.2).

2.3.2. In view of the absence of the term "specific crystal structure" in the claims as originally filed as well as in the granted claims, no objection under Article 84 EPC against its absence in the present claims can be allowed. Moreover, in the patent specification, "such a specific crystal structure" (page 3, lines 43 to 46) refers to the structures described before, which are defined by the powder X-ray diffraction pattern of present claim 1 as illustrated in the figures. Therefore, there is no reason to suppose that some essential crystal structure other than the one specified could have been meant in the description.

2.3.3. Therefore, the amendments do not give rise to objections under Article 84 EPC.

2.4. The amendments aim at overcoming the grounds of opposition, eg the ground of lack of novelty over D1 (Rule 57a EPC).

3. Sufficiency of disclosure

An invention is sufficiently disclosed within the meaning of Article 83 EPC if a person skilled in the art can carry it out on the basis of the information provided in the patent specification as filed in the light of the common general knowledge.

The patent specification is a written text addressed to a skilled person, who would consider the following elements when carrying out the invention:

(a) The explicit items of information as given in the specification;

(b) The relevant context thereof, ie the implicit items of information, which the skilled person understands when reading the specification, such as the direct and inevitable consequence of a described activity, or the content of a document explicitly referred to; and

(c) The common general knowledge, ie those items of fundamental knowledge that need not be addressed in the specification because they are available to the ordinary practitioner in the field who knows them from or is expected to find them in generally known information sources, such as textbooks and general technical literature. On the basis of such common general knowledge, the skilled person can supplement the text with the commonly known items of information (Case Law, supra, II.A.2(a)).

3.1. The respondent's objections regarding a lack of sufficiently clear and complete disclosure were based on two lines of argument: the catalyst performance and the method of manufacture, in particular the method of drying the catalyst before its calcination.

3.1.1. Regarding the former, the respondent argued that the patent in suit did not contain sufficiently clear and complete information in order to arrive at a catalyst having a conversion, selectivity and yield in the production of nitriles from alkanes as exemplified in the patent in suit.

3.1.2. Claim 1 concerns a catalyst for the production of a nitrile from an alkane, which is defined in structural terms and process features relating to the calcination conditions. It contains no requirements regarding performance apart from the suitability for the production of a nitrile from an alkane. Nor is a performance better than that of known catalysts required.

3.1.3. Whether or not a certain performance is achieved by the claimed catalysts may play a role in the assessment of inventive step under Article 56 EPC, if this technical result turns out to be the sole reason for the alleged inventiveness of the catalysts. However, if such an effect is not claimed it is irrelevant for the issue of sufficiency of disclosure (T 939/92, OJ EPO 1996, 309, Headnote point 2 and Reasons Nos. 2.4 to 2.6).

3.1.4. Therefore, the first line of argument of the respondent cannot be followed.

3.2.1. Regarding the second line of argument, concerning the drying of the catalyst, claim 1 is not restricted to any particular method of drying either.

3.2.2. According to the patent specification, three methods of drying may be used to manufacture the claimed catalysts: evaporation to dryness, spray-drying, and vacuum drying (page 3, lines 20 to 21).

3.2.3. In all of the 158 examples and 7 comparative examples of the patent in suit, the slurry had been evaporated to dryness to obtain a solid, before calcination. No details of drying are specified apart from a temperature which, if indicated, is 150°C.

3.2.4. The respondent argued that the desired catalyst could only be obtained when spray-drying was used as the drying method. The other two methods did not yield sufficiently active catalysts, even if they met the powder X-ray diffraction pattern as defined in claim 1, which was not always the case. Hence, the powder X-ray-diffraction pattern as defined in claim 1 could not be responsible for improved catalyst performance. The patent in suit did not elucidate that spray-drying was an essential feature of the method of manufacture of the claimed catalysts.

3.2.5. In support of its arguments, the respondent relied upon a number of experiments, which show the following picture (only the experiments which concern the use of Nb have been considered, since the present claims are restricted to said element):

(1) The first experiments were carried out by the respondent as detailed in the written statement setting out the grounds of opposition, dated 19. November 1996, points IIa to IIe and I:

(a) In order to demonstrate insufficiency of disclosure, Examples 1, 2, 24 and 33 of the patent in suit were carried out by evaporating a slurry at 100°C until a paste was obtained, which was then dried at 150°C for 16h and calcined under nitrogen at 620°C.

According to the respondent, these experiments resulted in catalysts whose powder X-ray diffraction patterns were in discrepancy from the patterns in Figures 1 and 2 of the patent in suit. Also, their performance was much lower than that of the catalysts exemplified in the patent in suit (propane conversion of 5.1, 9.9, 3.8 and 7.3 mol%, nitrile selectivity of 55.7, 56.1, 63.2 and 50.9 mol%).

The appellant, however, pointed out that these catalysts still met the requirements of claim 1, including the powder X-ray diffraction pattern (Statement of grounds of appeal, point 4.2).

(b) Reference Example 1 of D1 was carried out with a view to demonstrating lack of novelty. It resulted in a catalyst having a powder X-ray diffraction pattern within the definition of claim 1, which catalyst was suitable for the conversion of propane to acrylonitrile.

(2) Further experiments were submitted during the opposition proceedings with a letter dated 27. April 1998:

(a) For the issue of sufficiency, Examples 1, 2, 24. and 33 of the patent in suit were carried out by the respondent in a reactor different to that used the first time (point 3.2.5(1)(a), supra). According to the respondent, these experiments resulted in catalysts whose performance was much lower than that of the catalysts exemplified in the patent in suit (Propane conversion of 4.3, 8.5, 2.5 and 4 mol%, nitrile selectivity of 28, 29, 29 and 28 mol%).

(b) Example 1 of the patent in suit was also carried out by Mr Aoki (Declaration dated 23. April 1998, annexed Exhibit) under the following conditions: use of niobium hydrogenoxalate in aqueous ammonia instead of "ammonium niobium oxalate"; evaporation conducted at 100°C for 2h to obtain a paste which was subsequently dried overnight at 150°C and calcination under a nitrogen atmosphere. The obtained catalyst satisfied the powder X-ray diffraction pattern requirements of claim 1 and achieved a propane conversion of 10.4%, an acrylonitrile selectivity of 3.8% and an acrylonitrile yield of 0.4%.

The respondent drew the conclusion that a catalyst which satisfied the X-ray diffraction pattern of claim 1 did not achieve the high performance exemplified in the patent in suit.

(c) In relation to the issue of novelty, a further rerun of Reference Example 1 of D1 had been carried out by Asahi Chemical Industry Co., Ltd., under the supervision of Professor Maruno (Declaration dated 20 April 1998, annexed Exhibit) under the following conditions: use of niobium hydrogenoxalate in aqueous ammonia instead of "ammonium niobium oxalate"; evaporation conducted at 70°C (as specified in the description of D1) for 3h to obtain a paste which was subsequently dried overnight at 130°C and calcination under two different air flowing conditions. The catalyst fulfilled the requirements of claim 1.

(d) Since that result differed from the previous one of the respondent, in which the calcination had been interrupted prematurely, Reference Example 1 of D1 was carried out yet again by the respondent under the following conditions: evaporation of the slurry at 100°C until a paste was obtained, drying of that paste at 130°C for 16h and calcination at 350°C in air for 3h. The experiment resulted in a catalyst having a powder X-ray diffraction pattern within the definition of claim 1, which was suitable for conversion of propane to acrylonitrile. According to the respondent (then opponent), this demonstrated a lack of novelty of the claimed catalysts.

(e) In relation to the issue of inventive step, the catalyst obtained from the reproduction of Example 1 of the patent in suit was subjected to ammoxidation in the same reactor but under the conditions set out in D1, by the respondent. It resulted in a catalyst with a propane conversion of 3.8 mol% and a nitrile selectivity of 26 mol%. According to the respondent (then opponent), this demonstrated lack of inventive step, in particular because calcination under an inert atmosphere was known from (D3) DE-A-3 119 586.

(3) A third series of experiments was submitted in appeal proceedings, with a letter dated 10. September 1999:

(a) Regarding the issue of sufficiency of disclosure, Example 1, in which the Nb compound and the calcination conditions were varied, and Examples 2, 3 and 15 to 20 of the patent in suit were carried out by Professor Lintz ("Anlage 2": Declaration dated 30 July 1999) under drying conditions of 150°C for 3.5, 4, 5, 15, 17, 18, 66 or 68 hours and calcination conditions of 400, 500, 600 or 620°C for 2, 4, 5 or 10 hours.

None of the catalysts complied with the powder X-ray diffraction pattern of claim 1 in suit.

(b) Since Professor Lintz did not possess any equipment for the ammoxidation of propane to acrylonitrile, the respondent undertook further experiments ("Anlage 3") to show the performance of two of the catalysts obtained by Professor Lintz on the basis of Example 1 ("Probe 1.1" and "Probe 1.4", "Anlage 2") as well as that of further catalysts obtained under drying conditions of 150°C for 1.5h and calcination conditions of 400°C for 2h, 4h or 8h.

In the ammoxidation of propane to acrylonitrile, conversions of 27, 36, 42 and 39 mol%, selectivities of 30, 12, 16 and 12 mol%, and yields of 8, 4, 7 and 5 mol% were achieved.

(c) A further rerun of Example 1 of the patent in suit was carried out by Mr Aoki ("Anlage 4": Exhibit A to the Declaration dated 10. September 1999).

A catalyst obtained by drying at 150°C for 3.3h and calcining at 620°C for 2h fulfilled the powder X-ray diffraction pattern as well as the further conditions of claim 1 in suit and achieved a conversion of 15.7 mol%, a selectivity of 44.2 mol% and a yield of 6.9. mol% in the ammoxidation of propane.

(d) In relation to the issue of novelty, Reference Example 1 of D1 was again carried out by Asahi Chemical Industry Co., Ltd., under the supervision of Professor Maruno ("Anlage 5": Declaration dated 27 August 1999, annexed Exhibit) under the following conditions: use of ammonium niobium oxalate; evaporation of the slurry at 70°C until a paste was obtained, drying of that paste overnight at 130°C to obtain a dried precursor, calcination of that precursor under an air stream at 350°C for 2h, pulverization of the calcined catalyst to obtain a catalyst identified as "fresh catalyst", rinsing with oxalic acid, ammoxidation of propane under the conditions of Example 4 of D1 for 1h to obtain a catalyst identified as "used catalyst" and testing of both "fresh" and "used" catalysts.

According to the respondent, the catalysts satisfied the composition and X-ray requirements of claim 1 in suit, so that they were not distinct from the catalysts as claimed.

(4) A fourth series of experiments was submitted with a letter dated 15 November 2001:

(a) For the issue of sufficiency of disclosure, the respondent carried out 8 further experiments on the basis of Example 1 of the patent in suit, with variations in the drying methods and compositions.

(a1) In the first experiment ("Versuch 1") the catalyst solution was evaporated to dryness at 150°C for 30 min and calcined at 620°C for 2h. The X-ray diffraction pattern of the catalyst did not comply with that of claim 1 in suit. In two different tests, that catalyst had a conversion of 7 and 2 mol%, a selectivity of 27 and 28 mol% and a yield of 1.9 and 0.6 mol%.

(a2) Two further experiments ("Versuch 2" and "Versuch 3"), in which the slurry was spray-dried, resulted in catalysts fulfilling the requirements of claim 1 in suit with a conversion of 51 and 58.4 mol%, a selectivity of 60 and 44.8. mol% and a yield of 30.6 and 26.2. mol%, respectively, in the ammoxidation of propane.

(a3) In the next experiment ("Versuch 4"), the catalyst underwent an extra treatment, not indicated in the patent in suit, for the purpose of obtaining particular phases and crystal structures. That analysis was worked out in the following experiments ("Versuche 5, 6, 7"), in which it was shown that a particular phase identified with the letter "k" was inactive.

(a4) The last experiment ("Versuch 8") concerned a rerun of the third experiment ("Versuch 3") while applying an additional step of decomposition in air (275°C, 1h) of the dried precursor before calcination, described as an option in the patent in suit. It resulted in a catalyst fulfilling the conditions of claim 1 in suit and achieving a conversion of 62.8 mol%, a selectivity of 48.8 mol% and a yield of 30.4. mol%. Also, in comparison to "Versuch 3", a smaller loss of Te was observed. That catalyst was also further analysed as regards the crystal structures and their effects. The respondent's conclusion was that two particular crystal structures should be present for the catalyst to fulfil the conditions of claim 1 and be active, the presence of which was only achieved by spray-drying.

(b) Six catalysts were prepared on the basis of Example 37 of the patent in suit by Mr Aoki under the varying compositions and drying conditions detailed in the exhibits to the declaration dated 13 November 2001.

(b1) The first catalyst (Y-1) solution or slurry was evaporated to dryness at 150°C for 10h and then calcined at 600°C, 2h. The X-ray diffraction pattern of the catalyst complied with that defined in claim 1 in suit and the catalyst achieved a conversion of 4.5. mol%, a selectivity of 26.7 mol% and a yield of 1.2 mol% in the ammoxidation of propane.

(b2) The second catalyst (Y-2) solution was spray-dried and calcined at 600°C for 2h. The X-ray diffraction pattern complied with that defined in claim 1 in suit and the catalyst achieved a conversion of 65.9 mol%, a selectivity of 60.2 mol% and a yield of 39.7 mol% in the ammoxidation of propane.

(b3) Catalysts Y-3 to Y-6 were prepared with substantially the same procedure as in the production of catalyst Y-2, but different starting solutions, to show the effect of a particular phase on the catalyst performance. The last two (Y-5, Y-6) had a composition outside the claimed scope. The catalysts that fulfilled the requirements of claim 1 in suit exhibited a conversion of 1.2 and 0.8 mol%, a selectivity of 0 and 0. mol% and a yield of 0 and 0 mol%, respectively.

From these results the conclusion was drawn that the X-ray characteristics requirement defined in claim 1 in suit could not be responsible for suitable catalysts.

(c) For the purpose of demonstrating lack of novelty, a further rerun of Reference Example 1 of D1 was again carried out under the supervision of Professor Maruno (Declaration dated 24 October 2001, annexed Exhibit).

Three catalyst samples were prepared by carrying out three times Reference Example 1 of D1 and thereafter mixing the three catalysts thus obtained into a mixture.

The slurry was evaporated to dryness at 70°C until a paste was obtained, which paste was dried overnight at 130°C to obtain a dried precursor. Calcination of that precursor was carried out under an air stream at 350°C for 3h. The so calcined catalyst was pulverized and that procedure was repeated twice to obtain two additional samples. The three samples were mixed into a mixture identified as "fresh catalyst". That catalyst was rinsed with oxalic acid. An ammoxidation of propane was carried out under the conditions of Example 4 of D1 for 1h to obtain a catalyst identified as "used catalyst".

According to the respondent, both "fresh" and "used" catalysts satisfied the composition and X-ray requirements of claim 1 in suit. Hence, these catalysts were not distinct from the catalysts as claimed.

(d) The experiments carried out under the supervision of Professor Ueda concerned Example 1 of EP-B-0 608 838 and have no bearing to the question whether the patent in suit fulfils the requirements of Article 83 EPC.

(e) The two further declarations by Professor Maruno and Professor Lintz, respectively, which were also added to this series of experiments, inter alia dealt with the information which was necessary for a clear definition of a crystalline structure of a multi-metal-oxide.

(5) A fifth series of experiments was submitted with letter dated 4 September 2002:

The respondent carried out a further rerun of Example 1 of the patent in suit, but this time vacuum drying was applied to the slurry for 45 min at 55°C and 30 mbar, after which calcination took place at 620°C during 2 or 6h.

The resulting catalysts exhibit an X-ray diffraction pattern with peaks as defined in claim 1 in suit. However, the relative intensity of the peak at 28.2±0.3 fell outside the required range. The respondent drew the conclusion that vacuum drying was not suitable for obtaining the claimed catalysts.

The appellant objected that these experiments had been conducted too late, so that a proper analysis and the submission of counter-evidence had not been possible.

3.2.6. The appellant maintained that the respondent had not (correctly) repeated the examples of the patent in suit and, in their turn, relied upon a number of experiments annexed to the statement of the grounds for appeal dated 15 December 1998:

(1) Example 1 of the patent in suit had been carried out by Professor Iwasawa (Declaration dated 26. November 1998).

Catalysts were prepared using two different drying procedures, A and B.

In process A the slurry was sprayed on a commercially available Teflon-treated hot plate at 150°C and a powder was collected after 4 min. In Process B, the slurry was sprayed on a stainless steel plate and dried at 150°C for 15 min, after which a powder was collected.

The powders were again sprayed, dried and collected, and then calcined at 620°C for 2h.

The resulting catalysts exhibited an X-ray diffraction pattern as claimed and possessed a catalytic performance, as follows:

Catalyst of Process A: propane conversion of 83.5% and acrylonitrile yield of 43.8%.

Catalyst of Process B: propane conversion of 78% and acrylonitrile yield of 35.1%.

The appellant concluded that Professor Iwasawa, an independent expert who had not been asked to repeat the example but had arranged for it in the light of the common general knowledge in the field, was able to carry out the invention within the scope of claim 1 in suit, with an activity at a level comparable to that of Example 1 of the patent in suit.

(2) Professor Moro-Oka was asked by the appellant to rerun Example 37 of the patent in suit (Declaration dated 25 November 1998). The slurry was evaporated to a paste under stirring until the paste began to foam, which paste was dried to a solid at 150°C for 3 min. After pulverization of that solid, calcination was carried out at 600°C for 2h.

The resulting catalyst exhibited an X-ray diffraction pattern as claimed and had a catalytic performance in the ammoxidation of propane to acrylonitrile, as follows: propane conversion of 73.3% and acrylonitrile yield of 44.5%.

The appellant concluded that care should be taken during the preparation of the catalyst, but no more than that which a skilled person would normally apply. Therefore, no information beyond that in the patent was required in order to carry out the examples of the patent in suit.

4. From the above described experiments submitted by the respondent and the appellant, the following picture appears:

4.1. As regards the method of evaporation to dryness, the majority of the catalysts so prepared fulfil the requirements of claim 1 in suit in that they have the required X-ray diffraction pattern as well as properties that render them suitable for the production of a nitrile from an alkane.

4.1.1. In particular, in all of the respondent's experiments in which examples of the patent were carried out using evaporation to dryness, with the exception of those of Professor Lintz (point 3.2.5(3)(a) supra), the catalysts have the required features and, even though having a lower performance than described in the patent examples, are suitable for their purpose.

4.1.2. Regarding the catalyst performance, as already pointed out above (point 3.1.3), no specific performance, such as conversion, selectivity or yield, is required by the wording of claim 1 in suit, so that it is irrelevant for the issue of sufficiency of disclosure whether or not the performance is low. Moreover, it is a well-known fact that each catalyst needs its own optimal conditions for optimal performance and it has not been shown that the conditions actually used in the experiments were the optimal ones for the particular catalysts tested. The skilled person can however be expected to look for the optimal conditions for a given catalyst.

4.1.3. The catalysts resulting from the experiments carried out by Professor Lintz did not meet the X-ray diffraction pattern requirements of claim 1 in suit (point 3.2.5(3)(a) supra).

In these experiments, apart from the absence of any concentration (evaporation) of the slurry to a paste, a drying time ranging from 3.5 to 68h had been used, which according to the appellant was too long but according to the respondent was within the teaching of the patent.

The fact that the feature "drying an aqueous solution of ..." is defined in claim 1 without specifying the exact operating conditions thereof does not imply that any drying condition should lead to the claimed product, in order that the disclosure be sufficiently clear and complete. Rather, these conditions should follow the teaching of the patent in suit in its context as understood by the person skilled in the art.

In this respect, D1 represents background art for the patent in suit and discloses a suitable protocol for evaporation to dryness.

The mention of spray-drying in the patent in suit (page 3, lines 20 to 21) indicates that the catalysts are obtainable by a quick and uniform drying of the slurry, ie a long drying time was not a teaching of the patent.

In fact, it has not been shown why the skilled person on the basis of common general knowledge in the handling of a catalyst such as the one claimed, the delicacy of which has not been disputed, would not have preferred a short drying time, which moreover would be of economic advantage.

It has not been shown either that tests routinely carried out to establish the appropriate drying conditions would in the present case constitute an undue burden for the skilled person.

The fact that experiments may be devised with the help of which particular characteristics or lower performance can be caused to occur under specially controlled conditions is not appropriate proof of insufficiency.

Therefore, it cannot be excluded that the prolonged drying time used by Professor Lintz may have damaged the catalysts and influenced the relevant properties thereof. On the basis of the teaching of the patent as a whole it is to be assumed that the skilled person would have tried to avoid such a failure by shortening the drying time. Hence, the Board is not convinced that the failure of these examples can convincingly prove insufficiency.

4.1.4. The appellant's results confirm the above conclusions. The catalysts obtained from the experiments carried out by Professors Iwasawa and Moro-Oka for the appellant (points 3.2.6(1) and (2), supra) fulfil the requirements of claim 1 in suit with a good performance in the production of a nitrile from an alkane.

The respondent argued that the drying methods used in these experiments were exotic and the skilled person would never have arrived at them on the basis of the patent specification. However, the drying methods used in these experiments fall under the terms of "evaporation to dryness" and lead to catalysts fulfilling the requirements of claim 1 in suit.

Even if they were exotic and not immediately apparent, this would demonstrate that the claimed catalysts are obtainable by a method including a drying step which proceeds as quickly as possible, in line with the patent, and that the patentee had a legitimate interest also at protecting these products and methods. As will also become clear from the following, it has not been established that only exotic drying conditions result in products within the scope of claim 1.

4.1.5. In order to support the argument of lack of novelty, Reference Example 1 of D1 has been carried out five times, each time with the result that a catalyst was obtained that allegedly fulfilled the requirements of claim 1 in suit. In these experiments, the slurry was concentrated to a paste, eg for 3 hours at 70°C, and then dried, eg overnight at 130°C.

Since D1 belongs to the background of the invention as acknowledged in the patent in suit, see page 2, line 17 ("... we have described a Mo-V-Te-Nb-O catalyst ..."), and the only difference from the present catalyst preparation is the calcination under oxygen, instead of in its absence as now claimed, there can be no doubt that a skilled person was able to prepare a catalyst fulfilling the requirements of claim 1 in suit using evaporation to dryness.

4.1.6. In this light, the one catalyst prepared by the respondent (obtained by drying the slurry at 150°C for 30. min, without concentration (evaporation) of the slurry to a paste) which did not fulfil the requirements of claim 1 in suit (point 3.2.5(4)(a1), supra) cannot prove insufficiency of disclosure.

4.2. Regarding spray-drying, the respondent argued that although spray-drying was essential to achieve the claimed catalysts with the exemplified performance, such was not evident from the patent in suit and the skilled person became aware of its essentiality after reading EP-A-0 603 836 (GEH1), a later application of the appellant, in particular Comparative Example 1 thereof.

However, spray-drying was mentioned ab initio in the patent in suit as one of the possible ways for drying the slurry and it has not been argued that the determination of the relevant conditions required undue burden.

Furthermore, the argument that the catalyst of Comparative Example 1 of GEH1 presented further peaks in the diffraction pattern, which difference allegedly showed that spray-drying was necessary (letter dated 15. November 2001, pages 2 and 3) cannot be followed. Comparative Example 1 of GEH 1 does not disclose all the diffraction data, nor are the same conditions used as in the patent in suit, since the slurry was boiled to remove the water and no temperature is specified, contrary to Example 3 of the patent in suit. The catalyst obtained thereby was nevertheless suitable for the ammoxidation of propane to acrylonitrile. Therefore, at most the conclusion can be drawn that spray-drying resulted in an improvement, but not that it would be indispensable.

The respondent maintained that an active catalyst was obtainable if spray-drying was used and, since that was not the case with evaporation to dryness, spray-drying was an essential feature of the invention. No matter whether the argument of the essentiality of spray-drying refers to clarity or not, it cannot be followed in the light of the fact that: not all the catalysts obtained by spray-drying were active (point 3.2.5(4)(b3), supra) and, moreover, evaporation to dryness resulted in active catalysts.

4.3. As regards vacuum drying, a single experiment (point 3.2.5(5)(a), supra), which does not cover all of the possible ways of vacuum drying, resulted in a catalyst which did not fulfil the X-ray diffraction peaks of present claim 1. However, because of its filing shortly before the oral proceedings, that test could not be challenged by the appellant. Anyhow, one failed experiment is not sufficient proof that vacuum drying in general, as disclosed in the patent in suit, does not lead to the claimed catalysts. Therefore, the test is not relevant to this decision and the Board need not decide on its admission into the proceedings.

4.4. In respect of the experiments which did not achieve the desired result, the Board points out that although it may be possible to find conditions within a claim that do not result in the desired effect, eg by using extreme circumstances or correlations, the question to be answered is rather whether or not the skilled person using the best of his abilities and trying to succeed would, in reality, consider them. This applies particularly to features of a claim that are part of the operating conditions but do not form the core of the invention, such as, in the present case, the method of drying the catalyst slurry whereas the gist of the invention is formed by calcination in the absence of oxygen.

4.5. Regarding the respondent's argument that the patent lacked essential information about the exact crystal phase composition of the claimed catalysts, it is pointed out that knowledge of the exact composition of the catalysts is not a prerequisite as long as the guidance provided by the patent in suit is sufficient for the skilled person to obtain a catalyst having the required properties. Moreover, the respondent's argument is based on analytical experiments carried out with knowledge of the patent (point 3.2.5(4)(b3), supra).

4.6. In view of the above, the Board comes to the conclusion that the evidence submitted fails to establish that the skilled person would not have been able to carry out the invention without undue burden.

5. Although the Board has come to the conclusion that lack of sufficient disclosure has not been shown, the appellant's request that the patent be maintained on the basis of the claims submitted as the main request during the oral proceedings cannot be allowed at this stage of the proceedings because the grounds of opposition pursuant to Article 100(a) EPC have not yet been considered.

Therefore, in order to enable full consideration of the case by the Opposition Division, without depriving the parties of the possibility to be heard by two instances, the Board decides to remit the case to the first instance for further prosecution pursuant to Article 111(1) EPC.