Title of Invention	A METHOD FOR MANUFACTURING CEMENT CLINKER FROM PARTICULATE CEMENT RAW MATERIAL AND A PLANT FOR CARRYING OUT THE SAID METHOD
Abstract	A description is made of a method as well as an apparatus for manufacturing cement clinker from particulate cement raw material by which method fresh raw material is preheated and possibly precalcined in a suspension preheater (1, 3) by heat exchange with hot exhaust gases, and preheated and possibly precalcined material is finally calcined and burned into clinker in a rotary kiln (7), hot clinker from the rotary kiln is cooled in a cooler (9) and dust is separated from the exhaust gases from the preheater in a filter arrangement (11). The method and the apparatus are peculiar in that dust from the filter arrangement (11) is introduced into the material inlet end of the rotary kiln (7) in a direction which is contrary to the flow direction of the kiln gases.Hereby is obtained a significant reduction of coatings on the walls of the riser duct.

Title of Invention

A METHOD FOR MANUFACTURING CEMENT CLINKER FROM PARTICULATE CEMENT RAW MATERIAL AND A PLANT FOR CARRYING OUT THE SAID METHOD

Abstract

A description is made of a method as well as an apparatus for manufacturing cement clinker from particulate cement raw material by which method fresh raw material is preheated and possibly precalcined in a suspension preheater (1, 3) by heat exchange with hot exhaust gases, and preheated and possibly precalcined material is finally calcined and burned into clinker in a rotary kiln (7), hot clinker from the rotary kiln is cooled in a cooler (9) and dust is separated from the exhaust gases from the preheater in a filter arrangement (11). The method and the apparatus are peculiar in that dust from the filter arrangement (11) is introduced into the material inlet end of the rotary kiln (7) in a direction which is contrary to the flow direction of the kiln gases.Hereby is obtained a significant reduction of coatings on the walls of the riser duct.

Full Text	The present invention relates to a method for manufacturing cement clinker from particulate cement raw material. The invention also relates to a plant for carrying out the method according to the invention. Essentially all cement raw material mixtures contain at least small quantities of CI, K, Na and S, or such elements are added with the input fuel. In the burning zone of the kiln, there will be an evaporation of the various combinations of such elements, e. g. KCI, NaCI and KOH, whereas the sulphur will be gaseous in the form of SO2. At the cold end of the rotary kiln and in the smoke chamber or kiln riser duct there may be a condensation of various salts which will be present in the molten state given the prevailing temperatures of 900-1 lOO°C. Formation of sulphates may also occur. The salts act as a binder for the dust which will inevitably be present, and massive coatings may be formed, with attendant risk of blockage in the kiln riser duct. Removement of the coatings may necessitate suspension of operation, and the lining may be damaged either due to a reaction with the coatings or as a result of mechanical damage sustained during the clean-up operation. Up to this point in time, it has been common practice to introduce the preheated raw material into the kiln riser duct immediately after the discharge of exhaust gases from the rotary kiln since this would ensure that the salts are captured on the substantial surface of the raw material instead of on the walls. However, it may be difficult to achieve distribution of the preheated raw material in the exhaust gases across the entire cross-sectional area of the kiln riser duct. The reason for this is that the raw material is fed, via a downpipe, from the next-to lowermost cyclone, thus preventing it from attaining the velocity which is necessary to ensure distribution across the entire cross-sectional area which may have a width of several metres. From US patent No. 4.002.420 and US patent No. 4.108.593 methods and apparatuses are known where hot raw material is extracted from the next-tlowermost cyclone stage of the cyclone preheater and is introduced into the exhaust gases in the material inlet end of the kiln. Hereby is obtained a lowering of the temperature of the kiln gases, and thus certain condensation of undesirable vapours, such as alkali, chlorine and sulphur vapours, thereby reducing the problem of coatings in the kiln riser duct. However, the achieved reduction of coatings has proved to be insufficient. This may be ascribable to several factors. One explanation could be that the temperature is not reduced to sufficient extent and not with the speed required to ensure condensation of the vapours on the raw material particles in the exhaust gases instead of on the walls of the riser duct. Another explanation could be that the distribution of the raw material does not take place in sufficient degree of homogeneity across the cross-sectional area of kiln and/or that the specific surface area of the raw material is insufficient. A further general disadvantage of using preheated raw meal is that it will often contain salts in condensed form, and, at the prevailing temperatures, such salts may cause the particles to form lumps, thereby reducing the effective surface area for capturing the salts contained in the kiln gases. In the future, coatings in the kiln riser duct are expected to be a major problem because of the increase in the thermal loading of the kilns, while, at the same time, the kilns are shortened so that they can be supported by two piers instead of three. It is the objective of the present invention to provide a method as well as an apparatus for manufacturing cement clinker by means of which the aforementioned problems in terms of coatings in the kiln riser duct are substantially reduced. This is achieved by a method as described herein. Accordingly, the present invention provides a method for manufacturing cement clinker from particulate cement raw material, by which method fi'esh raw material is preheated and possibly precalcined in a suspension preheater subject to heat exchange with hot exhaust gases, preheated and possibly precalcined material is finally calcined and bumed into clinker in a rotary kiln, hot clinker from the rotary kiln is cooled off in a cooler and dust is separated from the exhaust gases from the preheater in a filter arrangement characterized in that dust from the filter arrangement is introduced into the material inlet end of the rotary kiln in a direction which is contrary to the flow direction of the kiln gases The temperature of the filter dust is typically less than 300^C and may be appropriately injected with the aid of pressurized gas into the material inlet end of the rotary kiln using means comprising a lance which terminates in the smoke chamber of the rotary kiln or in the rotary kiln itself, and extending substantially parallel to the longitudinal axis of the rotary kiln. Hereby is obtained a significant reduction of coatings on the walls of the riser duct. The underlying cause is partly that the temperature of the filter dust is lower than that of the preheated raw material, thereby allowing it to absorb a greater amount of condensation heat, and partly that the filter dust constitutes the finest fraction of the raw material, which means that it has a substantial surface area, and partly that the fitter dust is injected in a direction which is contrary to the flow direction of the kiln gases, ensuring even distribution in the kiln gases across the entire cross-section of the kiln. Up to this point in time, it has been standard practice to blend the filter dust into the raw material mixture prior to its introduction into the preheater. By extracting at least some of the filter dust and introducing it into the material inlet end of the rotary kiln as proposed according to the present invention will lead to a moderate reduction in the efficiency of the heat exchange process in the preheater. However, this immediate disadvantage is compensated by the fact that the raw material will attain better powder properties in the cyclones when the content of filter dust is reduced. As a result, there will be a smaller internal dust circulation in the preheater, thus enhancing the efficiency of the preheater, and downtime due to cyclone blockages is also expected to decrease. Furthermore, the loading of the filter in terms of tonnes of dust per hour to be collected by the filter will be reduced, generating savings as far as the dust conveying devices are concerned. According to the invention, it may be preferred to utilize the entire filter dust volume and not just a partial volume as a means of combating coatings by injecting it into the material inlet end of the rotary kiln. An important spin-off benefit is thus achieved. Thus, by injecting the filter dust deep within the kiln system it will easier to control the clinker chemistry. Ordinarily, the composition of the filter dust exhibits deviations in relation to the rest of the raw material, and may, for example, have an excessive lime content, for example up to 200 in LSF. If the filter dust is returned to the raw material silo as previously practised, it will be necessary to ensure effective blending, with the primary aim being to maintain a raw material composition deviating somewhat from that which is necessary for the clinker. However, if it is preferred to inject the entire filter dust volume into the kiln, the composition of raw material needs only to be adjusted to extent where it deviates slightly-corresponding to the ash content in the fuels-from the desired clinker chemistry. In this context, it is a foregone conclusion that the raw mill plant comprises means for separating the cement raw materials from the exhaust gases which are subsequently vented to the filter arrangement for final dedusting. Whenever the filter arrangement is also used for separating the cement raw materials, it is preferred, to maximum practicable extent, that the finest filter fraction(s) be used for injection into the rotary kiln. According to the present invention, it will be possible to introduce cold raw material and/or fly ash simultaneously with the filter dust. Brief description of the accompanying drawing The invention will now be explained in further details with reference to the Figure 1 of drawing, being diagrammatical, and its only figure shows a plant according to the invention for manufacturing cement. The figure 1 depicts a plant for manufacturing cement which comprises a multistage suspension preheater 1, a calciner 3, which is fed with fuel via a number of burners 4 and combustion air via a kiln riser duct 5 and a smoke chamber 6, a rotary kiln 7, which is fed with fuel via a burner 8, a clinker cooler 9 and a filter arrangement 11. Raw material from an unspecified mill department 13 is introduced into the preheater 1 at F. From here it is conducted in counter-flow to the hot exhaust gases from the rotary kiln 7 down through the preheater 1 and the calciner 3. From the separating cyclone of the calciner 3 the calcined raw material is directed to the rotary kiln 7 in which it is burned into cement clinker which is subsequently cooled in the cooler 9. The kiln gases travel in the opposite direction from the cooler 9 through the rotary kiln 7 in which it is heated and continues up through the smoke chamber 6, the kiln riser duct 5, the calciner 4 and the preheater 1, and it is drawn through the kiln system by means of a fan 15. During the preheating process, it is inevitable that a portion, particularly the finest part of the raw materials, is not effectively separated in the cyclones of the preheater, instead being entrained in the exhaust gases, and, via the fan 15 and possibly the mill department, ending up in the filter arrangement 11. To eliminate the problem mentioned in the introduction in terms of coatings in the kiln riser chamber 5, it is proposed according to the invention to introduce dust from the filter arrangement 11 into the material inlet end of the rotary kiln 7. The filter dust may be appropriately injected with the aid of pressurized gas into the material inlet end of the rotary kiln 7 by means of a lance 17 which is terminated in the smoke chamber 6 of the rotary kiln or in the rotary kiln 7 itself, and extending substantially parallel to the longitudinal axis of the rotary kiln. So, during the operation of the plant according to the invention dust from the filter arrangement 11 is injected into the kiln 7 in counterflow to the kibi gases. Normally, the dust will be cooled down to a temperature of less than 300°C and often as low as 100 to 150° in the filter arrangement 11, and, furthermore, it will be present in an amount sufficient to ensure proper cooling of the kiln gases in the material inlet end of the rotary kiln 7. The injection of the filter dust may be controlled in order to obtain the optimum cooling of the kiln gases depending on which salts are present in the gases. The injection of the filter dust entails that the temperature of the kiln gases in the material inlet end of the kiln 7 may be cooled down from the range 900 to 1200^C to a range about 830 to 850°C, which is the decarbonization temperature of the main material component calcium carbonate, thus resulting in the condensation of the salts on the surface of the fine filter dust particles. The invention has been field-tested at an operating cement plant and as a result of the test the need to perform clean-out work in the riser duct 5 was reduced fi'om once every 8 hours to once a week. WE CLAIM: 1. A method for manufacturing cement clinker from particulate cement raw material, by which method fresh raw material is preheated and possibly precalcined in a suspension preheater (1, 3) subject to heat exchange with hot exhaust gases, preheated and possibly precalcined material is finally calcined and burned into clinker in a rotary kiln (7), hot clinker from the rotary kiln is cooled off in a cooler (9) and dust is separated from the exhaust gases from the preheater in a filter arrangement (11) characterized in that dust from the filter arrangement (11) is introduced into the material inlet end of the rotary kiln (7) in a direction which is contrary to the flow direction of the kiln gases 2. The method as claimed in claim 1, wherein the entire filter dust volume from the filter arrangement (11) is introduced into the material inlet end of the rotary kiln (7) in a direction which is contrary to the flow direction of the kiln gases. 3. The method as claimed in claim 1 or 2, wherein the filter dust is injected into the rotary kiln (7) by pressurized gas, 4. The method as claimed in claim 1 or 2, wherein cold raw material and flyash is introduced simultaneously with the filter dust. 5. A plant for carrying out the method as claimed in claim 1, comprising a multistage suspension preheater (1), a calciner (3) with a number of burners (4), a kiln riser duct (5), a smoke chamber (6), a rotary kiln (7) with a bumer (8), a clinker cooler (9) and a filter arrangement (11), characterized in that it comprises means (17) for introducing dust from the filter arrangement (11) into the material inlet end of the rotary kiln (7) in a direction which is contrary to the flow direction of the kiki gases. 6. The plant as claimed in claim 6, wherein the means (17) of introduction comprise a lance which is terminated in the smoke chamber (6) of the rotary kiln or in the rotary kiln (7) itself, and which extends parallel to the longitudinal axis of the rotary kiln. 7. A method for manufacturing cement clinker from particulate cement raw material, substantially as hereinabove described and illustrated with reference to the accompanying drawings.

Full Text

The present invention relates to a method for manufacturing cement clinker from particulate cement raw material. The invention also relates to a plant for carrying out the method according to the invention.
Essentially all cement raw material mixtures contain at least small quantities of CI, K, Na and S, or such elements are added with the input fuel. In the burning zone of the kiln, there will be an evaporation of the various combinations of such elements, e. g. KCI, NaCI and KOH, whereas the sulphur will be gaseous in the form of SO2. At the cold end of the rotary kiln and in the smoke chamber or kiln riser duct there may be a condensation of various salts which will be present in the molten state given the prevailing temperatures of 900-1 lOO°C. Formation of sulphates may also occur. The salts act as a binder for the dust which will inevitably be present, and massive coatings may be formed, with attendant risk of blockage in the kiln riser duct. Removement of the coatings may necessitate suspension of operation, and the lining may be damaged either due to a reaction with the coatings or as a result of mechanical damage sustained during the clean-up operation.
Up to this point in time, it has been common practice to introduce the preheated raw material into the kiln riser duct immediately after the discharge of exhaust gases from the rotary kiln since this would ensure that the salts are captured on the substantial surface of the raw material instead of on the walls. However, it may be difficult to achieve distribution of the preheated raw material in the exhaust gases across the entire cross-sectional area of the kiln riser duct. The reason for this is that the raw material is fed, via a downpipe, from the next-to lowermost cyclone, thus preventing it from attaining the velocity which is necessary to ensure distribution across the entire cross-sectional area which may have a width of several metres.
From US patent No. 4.002.420 and US patent No. 4.108.593 methods and apparatuses are known where hot raw material is extracted from the next-tlowermost cyclone stage of the cyclone preheater and is introduced into the exhaust gases in the material inlet end of the kiln. Hereby is obtained a lowering of the temperature of the kiln gases, and

thus certain condensation of undesirable vapours, such as alkali, chlorine and sulphur vapours, thereby reducing the problem of coatings in the kiln riser duct. However, the achieved reduction of coatings has proved to be insufficient. This may be ascribable to several factors. One explanation could be that the temperature is not reduced to sufficient extent and not with the speed required to ensure condensation of the vapours on the raw material particles in the exhaust gases instead of on the walls of the riser duct. Another explanation could be that the distribution of the raw material does not take place in sufficient degree of homogeneity across the cross-sectional area of kiln and/or that the specific surface area of the raw material is insufficient.
A further general disadvantage of using preheated raw meal is that it will often contain salts in condensed form, and, at the prevailing temperatures, such salts may cause the particles to form lumps, thereby reducing the effective surface area for capturing the salts contained in the kiln gases.
In the future, coatings in the kiln riser duct are expected to be a major problem because of the increase in the thermal loading of the kilns, while, at the same time, the kilns are shortened so that they can be supported by two piers instead of three.
It is the objective of the present invention to provide a method as well as an apparatus for manufacturing cement clinker by means of which the aforementioned problems in terms of coatings in the kiln riser duct are substantially reduced.
This is achieved by a method as described herein.
Accordingly, the present invention provides a method for manufacturing cement clinker from particulate cement raw material, by which method fi'esh raw material is preheated and possibly precalcined in a suspension preheater subject to heat exchange with hot exhaust gases, preheated and possibly precalcined material is finally calcined and bumed into clinker in a rotary kiln, hot clinker from the rotary kiln is cooled off in a cooler and dust is separated from the exhaust gases from the preheater in a filter

arrangement characterized in that dust from the filter arrangement is introduced into the material inlet end of the rotary kiln in a direction which is contrary to the flow direction of the kiln gases
The temperature of the filter dust is typically less than 300^C and may be appropriately injected with the aid of pressurized gas into the material inlet end of the rotary kiln using means comprising a lance which terminates in the smoke chamber of the rotary kiln or in the rotary kiln itself, and extending substantially parallel to the longitudinal axis of the rotary kiln.
Hereby is obtained a significant reduction of coatings on the walls of the riser duct. The underlying cause is partly that the temperature of the filter dust is lower than that of the preheated raw material, thereby allowing it to absorb a greater amount of condensation heat, and partly that the filter dust constitutes the finest fraction of the raw material, which means that it has a substantial surface area, and partly that the fitter dust is injected in a direction which is contrary to the flow direction of the kiln gases, ensuring even distribution in the kiln gases across the entire cross-section of the kiln.
Up to this point in time, it has been standard practice to blend the filter dust into the raw material mixture prior to its introduction into the preheater. By extracting at least some of the filter dust and introducing it into the material inlet end of the rotary kiln as proposed according to the present invention will lead to a moderate reduction in the efficiency of the heat exchange process in the preheater. However, this immediate disadvantage is compensated by the fact that the raw material will attain better powder properties in the cyclones when the content of filter dust is reduced. As a result, there will be a smaller internal dust circulation in the preheater, thus enhancing the efficiency of the preheater, and downtime due to cyclone blockages is also expected to decrease. Furthermore, the loading of the filter in terms of tonnes of dust per hour to be collected by the filter will be reduced, generating savings as far as the dust conveying devices are concerned.

According to the invention, it may be preferred to utilize the entire filter dust volume and not just a partial volume as a means of combating coatings by injecting it into the material inlet end of the rotary kiln. An important spin-off benefit is thus achieved. Thus, by injecting the filter dust deep within the kiln system it will easier to control the clinker chemistry. Ordinarily, the composition of the filter dust exhibits deviations in relation to the rest of the raw material, and may, for example, have an excessive lime content, for example up to 200 in LSF. If the filter dust is returned to the raw material silo as previously practised, it will be necessary to ensure effective blending, with the primary aim being to maintain a raw material composition deviating somewhat from that which is necessary for the clinker. However, if it is preferred to inject the entire filter dust volume into the kiln, the composition of raw material needs only to be adjusted to extent where it deviates slightly-corresponding to the ash content in the fuels-from the desired clinker chemistry. In this context, it is a foregone conclusion that the raw mill plant comprises means for separating the cement raw materials from the exhaust gases which are subsequently vented to the filter arrangement for final dedusting. Whenever the filter arrangement is also used for separating the cement raw materials, it is preferred, to maximum practicable extent, that the finest filter fraction(s) be used for injection into the rotary kiln.
According to the present invention, it will be possible to introduce cold raw material and/or fly ash simultaneously with the filter dust.
Brief description of the accompanying drawing
The invention will now be explained in further details with reference to the Figure 1 of drawing, being diagrammatical, and its only figure shows a plant according to the invention for manufacturing cement.
The figure 1 depicts a plant for manufacturing cement which comprises a multistage suspension preheater 1, a calciner 3, which is fed with fuel via a number of burners 4

and combustion air via a kiln riser duct 5 and a smoke chamber 6, a rotary kiln 7, which is fed with fuel via a burner 8, a clinker cooler 9 and a filter arrangement 11.
Raw material from an unspecified mill department 13 is introduced into the preheater 1 at F. From here it is conducted in counter-flow to the hot exhaust gases from the rotary kiln 7 down through the preheater 1 and the calciner 3. From the separating cyclone of the calciner 3 the calcined raw material is directed to the rotary kiln 7 in which it is burned into cement clinker which is subsequently cooled in the cooler 9. The kiln gases travel in the opposite direction from the cooler 9 through the rotary kiln 7 in which it is heated and continues up through the smoke chamber 6, the kiln riser duct 5, the calciner 4 and the preheater 1, and it is drawn through the kiln system by means of a fan 15. During the preheating process, it is inevitable that a portion, particularly the finest part of the raw materials, is not effectively separated in the cyclones of the preheater, instead being entrained in the exhaust gases, and, via the fan 15 and possibly the mill department, ending up in the filter arrangement 11.
To eliminate the problem mentioned in the introduction in terms of coatings in the kiln riser chamber 5, it is proposed according to the invention to introduce dust from the filter arrangement 11 into the material inlet end of the rotary kiln 7. The filter dust may be appropriately injected with the aid of pressurized gas into the material inlet end of the rotary kiln 7 by means of a lance 17 which is terminated in the smoke chamber 6 of the rotary kiln or in the rotary kiln 7 itself, and extending substantially parallel to the longitudinal axis of the rotary kiln.
So, during the operation of the plant according to the invention dust from the filter arrangement 11 is injected into the kiln 7 in counterflow to the kibi gases. Normally, the dust will be cooled down to a temperature of less than 300°C and often as low as 100 to 150° in the filter arrangement 11, and, furthermore, it will be present in an amount sufficient to ensure proper cooling of the kiln gases in the material inlet end of the rotary kiln 7. The injection of the filter dust may be controlled in order to obtain the optimum cooling of the kiln gases depending on which salts are present in the

gases. The injection of the filter dust entails that the temperature of the kiln gases in the material inlet end of the kiln 7 may be cooled down from the range 900 to 1200^C to a range about 830 to 850°C, which is the decarbonization temperature of the main material component calcium carbonate, thus resulting in the condensation of the salts on the surface of the fine filter dust particles.
The invention has been field-tested at an operating cement plant and as a result of the test the need to perform clean-out work in the riser duct 5 was reduced fi'om once every 8 hours to once a week.

WE CLAIM:
1. A method for manufacturing cement clinker from particulate cement raw
material, by which method fresh raw material is preheated and possibly precalcined in
a suspension preheater (1, 3) subject to heat exchange with hot exhaust gases,
preheated and possibly precalcined material is finally calcined and burned into clinker
in a rotary kiln (7), hot clinker from the rotary kiln is cooled off in a cooler (9) and
dust is separated from the exhaust gases from the preheater in a filter arrangement (11)
characterized in that dust from the filter arrangement (11) is introduced into the
material inlet end of the rotary kiln (7) in a direction which is contrary to the flow
direction of the kiln gases
2. The method as claimed in claim 1, wherein the entire filter dust volume from the
filter arrangement (11) is introduced into the material inlet end of the rotary kiln (7) in
a direction which is contrary to the flow direction of the kiln gases.
3. The method as claimed in claim 1 or 2, wherein the filter dust is injected into the rotary kiln (7) by pressurized gas,
4. The method as claimed in claim 1 or 2, wherein cold raw material and flyash is introduced simultaneously with the filter dust.
5. A plant for carrying out the method as claimed in claim 1, comprising a
multistage suspension preheater (1), a calciner (3) with a number of burners (4), a kiln
riser duct (5), a smoke chamber (6), a rotary kiln (7) with a bumer (8), a clinker cooler
(9) and a filter arrangement (11), characterized in that it comprises means (17) for
introducing dust from the filter arrangement (11) into the material inlet end of the
rotary kiln (7) in a direction which is contrary to the flow direction of the kiki gases.

6. The plant as claimed in claim 6, wherein the means (17) of introduction comprise
a lance which is terminated in the smoke chamber (6) of the rotary kiln or in the
rotary kiln (7) itself, and which extends parallel to the longitudinal axis of the rotary
kiln.
7. A method for manufacturing cement clinker from particulate cement raw
material, substantially as hereinabove described and illustrated with reference to the
accompanying drawings.

Documents:

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in-pct-2002-1530-che-abstract.pdf

in-pct-2002-1530-che-claims filed.pdf

in-pct-2002-1530-che-claims granted.pdf

in-pct-2002-1530-che-correspondnece-others.pdf

in-pct-2002-1530-che-correspondnece-po.pdf

in-pct-2002-1530-che-description(complete)filed.pdf

in-pct-2002-1530-che-description(complete)granted.pdf

in-pct-2002-1530-che-drawings.pdf

in-pct-2002-1530-che-form 1.pdf

in-pct-2002-1530-che-form 26.pdf

in-pct-2002-1530-che-form 3.pdf

in-pct-2002-1530-che-form 5.pdf

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Patent Number

209503

Indian Patent Application Number

IN/PCT/2002/1530/CHE

PG Journal Number

50/2007

Publication Date

14-Dec-2007

Grant Date

04-Sep-2007

Date of Filing

24-Sep-2002

Name of Patentee

M/S. F.L. SMIDTH & CO A/S

Applicant Address

Vigerslev Allé 77, DK-2500 Valby, Copenhagen

Inventors:

#	Inventor's Name	Inventor's Address
1	HUNDEBÖL, Sören	Jernbane Allé 21 DK-2720 Vanlöse

PCT International Classification Number

C04B 7/43

PCT International Application Number

PCT/IB2001/000054

PCT International Filing date

2001-01-19

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	PA200000531	2000-03-30	Denmark