Indian Patents. 221091:METHOD FOR PRODUCING AN OXYGEN-CONTAINING COMPOUND USED AS FUEL ADDITIVE, IN PARTICULAR IN DIESEL FUELS, GASOLINE AND RAPESEED METHYLESTER

Title of Invention	METHOD FOR PRODUCING AN OXYGEN-CONTAINING COMPOUND USED AS FUEL ADDITIVE, IN PARTICULAR IN DIESEL FUELS, GASOLINE AND RAPESEED METHYLESTER
Abstract	The invention concerns a method for producing an oxygen-containing compound used as fuel additive, in particular in diesel fuels, gasoline and rapeseed methyl ester. Said method consists in a) reacting a polyvalent alcohol with an aldehyde or a Ketone to produce an acetal and b) etherifying the subsisting free hydroxyl groups in the acetal produced at step a) with tertiary olefins.

Full Text	FORM 2 THE PATENT ACT 1970 (39 of 1970) The Patents Rules, 2003 COMPLETE SPECIFICATION (See Section 10, and rule 13) TITLE OF INVENTION METHOD FOR PRODUCING AN OXYGEN-CONTAINING COMPOUND USED AS FUEL ADDITIVE, IN PARTICULAR IN DIESEL FUELS, GASOLINE AND RAPESEED METHYLESTER GRANTED APPLICANT(S) a) Name b) Nationality c) Address AND a) Name b) Nationality c) Address KOUSEMAKER, MICHIEL ARJAAN NETHERLANDS National EEMS 23, 9414EE GASSELTERNIJVEEN NETHERLANDS THIELE, KLAUS DIETER GERMAN National TROCKENER KAMP 19, 31139 HILDESHEIM GERMANY 17-12-2007 PREAMBLE TO THE DESCRIPTION The following specification particularly describes the invention and the manner in which it is to be performed : - ORIGINAL OBTECT OF THE INVENTION The invention describes the use and production of an oxygen-containing compound in Diesel fuels, gasoline, and rapeseed methyl easter, with which the readiness for ignition is increased and the particle emission is reduced. These improvements are achieved, for example, by a) production of 2,2 dimethyl-4-hydroxymethyl-l,3 dioxolan from glycerine and acetone and b) reacting of the 2,2 dimethyl-4-hydroxymethyl,l,3 dioxolan produced in step a) with isobutane in order to etherify the remaining CH group. DESCRIPTION OF THE PRIOR ART The addition of oxygen compounds to fuels in the form of alcohols and ethers has proved its value. As a result of such use, it has proved possible to do away with the ecologically questionable lead compounds which served as anti-knock means in fuels. The problem therefore arose of producing a compound by the derivation of the glycerine molecule which is suitable as a fuel component. The following compound classes are suitable compound classes which have in part already been publicised and are subject to protective rights: Glycerine ether Glycerine ester Glycerine scetals Glycerine ether The production of glycerine ethers has been protected in a number of patent specifications. For example, the patent specification US 1 966 033 describes the etherification of multivalent alcohols. The reacting of multivalent alcohols and tertiary olefins is dealt with in terms of protective rights under DE 4 223183, A method variant for the large- scale technical production of glycerine ethers is developed in EP 649 829. In addition to this general description for the production of glycerine ethers, special catalyst systems for use in this product class have been examined In various patent specifications. In DE 1 224 294 acidic fixed-bed catalysts are used for the reaction. Glycerine ethers occur as a by-product in the separation of tertiary olefins from the Q fraction in the distillation of crude oil. This is dealt with in Patent Specification US 1 968 601. In Patent Specification US 4 605 787 the production of alkyi tertiary alkyi ethers is described, whereby acidic zeolites are used as catalyst systems. The glycerine ethers are also used as phase agents in the reaction of glycerine and isobutene in DE 1 224 294. In WO 94/01389 the production of polyalkyl ethers from polyhydroxy compounds with a high molecular weight is described. Not only have the individual method steps for the production of glycerine ethers been dealt with in terms of patent law, but also their use as fuel components in Diesel fuels and gasoline. It is known that the addition of oxygen-containing compounds In fuels result in an improvement in quality. In WO 81/00721 a fuel mixture is described which has been modified by the addition of alcohols, water, ethers and vegetable oil. The Patent Specification US 4 353 710 is also concerned with the modification of Diesel fuels with ethers and esters. The addition of ethers to Diesel fuels has been described in DE 3 140 382. The improvement of Diesel fuel quality by the addition of aliphatic polyethers has been proven in the Patent Specification US 2 655 440. A mixture of alcohol and oxygenated hydrocarbons with a. molecular weight from 250-500 was used in Patent Specification US 4 753 661 for improving the quality of gasoline and Diesel fuel. The invention described in US 5 308 365 relates to a Diesel qualify with low sulphur content by the addition of dialkyl and trialkyl derivatives of glycerine. The use of these glycerine ethers is intended to serve to eliminate hydrophilicity, to incur a reduction in the boiling temperature in the range of the boiling diagram of the fuel components, and to achieve a reduction in density while maintaining the cetane number. The disadvantage with these substances is that a glycerine-ether mixture is formed with a maximum of 11 % oftriethers. The remainder consists of monoethers anddiethers, which because of the hydroxyl groups still present are in part not soluble in the individual fuel components. ' • ' Due to the steric hindrance, 100 % conversion to triethers is not possible. The conversion reaction to glycerine others is almost thermoneutral and heavily entropic. This leads to the situation that, as the temperature increases, the yield is reduced and oligomerisation sets in. With a reduction in the reaction temperature, however, the reaction is slowed to such an extant that no reaction worth mentioning takes place. Glycerine esters The production of glycerine esters is described in the GDR Patent Specification 156 803, This relates to the production of triacetir. The esterisation to lower glycerine esters does indeed bring the boiling point into the range of the Diesel fuel, but with a longer acryl reside no adequate ignition behaviour is achieved. On the other hand, the boiling behaviour of the triacetin is too high and therefore excludes use in gasoline. With glycerine esters, which lie within the boiling range of the conventional fuel components, solubility in the fuels is no longer guaranteed. The disadvantage of this substance class lies in the inadequate physical characteristics which exclude use in gasoline fuels, and the deficient ignition readiness in Diesel fuels. Glycerine acetals The production of glycerine acetates is described in the publications by R.R. TinK, E.Y. Speneer, J.M. Roxburg - Cann. J. Techn. 29 243 (1951) and R.R. Tink; A.C. Neish - Can. J. Techn 29 243 (1951) using the example of the reaction of glycerine with butyraldehyde. Dioxalans with longer alkyl residues, the production of which is described by C. Diantadosi (J. Org. Chem. 80;6613 (1958)) do not come into consideration for economic reasons. Determinant for admixture in Diesel fuel, gasoline, and rapeseed methyl ester is its solubility in these fuel components. This is very problematic due to the hydroxyl group which is present, however Even if the boiling position of the glycerine in its acetals is drastically reduced, the density in all cases is perceptibly above 1.02 g/ml. The use of these acetals in Diesel fuel was disappointing due to its poor; ignition behaviour. BRIEF DESCRIPTION OF THE INVENTION Glycerine, as an extremely hydrophilic substance, cannot be mixed either with gasoline (OK) or with Diesel fuel (DK) and rapeseed methyl ester (RME). The problem is to derivatise glycerine in such a way that the products can be used as fuel components in DK,. OK, and rapeseed methyl ester- To do this, it is necessary for it to be made compatible with fuels in order to fulfil the fuel standards. Compatibility with DK, OK, and RME is achieved by a complete reaction of the hydroxyl groups present at the glycerine molecule, on the one hand by the conversion of acetal and the etherificatlon of the hydroxyl group still present by means of a tertiary olefin. The derivatives produced in this way can be mixed in any proportion with DK, OK, and RME. The addition of such substances resulted in a lower particle emission and a better ignition readiness than pure DK, OK, or RME. Example of production In a first reaction step, for example, glycerine is reacted with acetone to 2, 2-dimethyl-4-hydroxymethyl-1, 3 dioxalan. Next, the 2,2-dimethyl-4-hydroxymethyl-l,3 dioxalan is etherified in an acidic catalyst reaction with isobutene. Production of 2,2-dimethyl-4-hydroxymethyl-l,3 dioxalan In a 5-litre flask 600 g of glycerine (free of water), 3600 g acetone, and 2,5 g p-toluol sulphonic acid are mixed under powerful stirring. The reaction mixture, is stirred at room temperature and then mixed with 60 g potassium carbonate (free of water). After further stirring for about 1 hour the reaction mixture is filtrated and the filtrate distilled in fractioned form. After a forerun of acetone, which can be used in a further reaction, distillation takes place at a pressure of 15 Torr of the 2,2-dimethyl-4-hydroxymethyl-l,3 dioxalan in a boiling range from. 82-84 °C The yield is 550 - 600 g. According to gas chromatic testing, the substance contained a purity of > 98 % and a refraction index of n = 1,432. Production of, 2,2-dimethyl-4-hydroxymethyl-l,3 dioxalan tert butyl ether 300 g of the 2,2-dimethyl-4-hydroxymethyl-l,3 dioxalan is presented in an autoclave with 2.5 g p-toluol sulphonic acid and cooled to -30 °C. 600 g isobutene is then added. This mixture is brought to reaction with a magnetic stirrer at 90 °C. After a relatively small forerun, the end product moves at 20 Torr into a boiling interval of 82-85°C. The reactions described are repeated several times over and produce on average yields of 300 g. According to gas chromatographic testing, with the reaction described a purity of > 95 % was obtained and a refraction index no. dependent on the purity, of 1.4190 -1.4260. In order to obtain a purity of > 99 %, phenyl isocyanate was added to the distillate and heated under backflow. Fractioning then again took place in a vacuum. The desired product in this case was obtained, according to gas chromatographic testing, in a purity of > 99%. The use of 2,2-dimethyl-4-hydroxymethyl-l, 3 dioxalan tert butyl ether (STBE) as a fuel component The substance described above was mixed as an additive to Diesel fuels, gasolines, and rapeseed ethyl esters. In this situation we determined that the particle emission is reduced in the form of clouding and the readiness to ignite increased in the form of dp max. Clouding [%] dp max bar/0 kW 6.68 8.13 5.61 6.43 2.20 1.16 1.03 0.00 Conventional commercial Diesel fuel Diesel fuel+ 20% STBE RME RME + 20 % STBE We claim: 1. Method for producing an oxygen-containing compound used as fuel additive, in particular in Diesel fuels, gasoline, and rapeseed methyl ester, characterised by a) Reaction of a multivalent alcohol with an aldehyde or ketone to produce an acetal, and b) Etherification of the still free hydroxyl groups of the acetal produced in step a) with tertiary olefins. 2. Method according to Claim 1, characterised in that the multivalent alcohol in step a) is selected from the group which comprises trivalent to hexavalent alcohols, in particular triols such as glycerine, tetrols, pentols, trimethylolpropane, penta erythrite and sugar alcohols with 4 to 6 hydroxyl groups. 3. Method according to Claim 1 or 2, characterised in that the aldehyde, the dialdehyde, or the ketone in step a) contains three to seven carbon atoms, wherein preferably acetaldehyde, acetone, or butyral aldehyde can be used. 4. Method according to one of Claims 1 to 3, characterized in that the tertiary olefin in step b) is selected from the group which comprises i-butene, 2-methyl-l-butene, 2-methyl-2-butene, isomer hexene with a tertiary carbon atom at the double bond, isomer heptene with a tertiary carbon atom at the double bond, and hydrocarbon mixtures which contain i-butene, such as in raffinate 1 of the crude oil distillation, and for preference C4 and/or C5 tert. alkenes. 5. Method according to one of Claims 1 to 4, characterised in that the raw materials for producing the oxygen-containing compound are selected in such a way that the oxygen-containing compound produced dissolves completely in the fuel, in particular in Diesel fuel, gasoline, and/or rapeseed methyl ester. 6. Method according to one of Claims 1 to 5, characterised in that the raw materials for producing the oxygen-containing compound are selected in such a way that the addition of the oxygen-containing compound produced to the fuel, in particular to Diesel fuel, gasoline, and/or rapeseed methyl ester, does not exert a negative influence on the flash point of the fuel, in particular of the Diesel fuel, gasoline, and/or rapeseed methyl ester. 7. Method according to one of Claims 1 to 6, characterised in that the raw materials for producing the oxygen-containing compound are selected in such a way that the addition of the oxygen-containing compound produced to the fuel, in particular to Diesel fuel, gasoline, and/or rapeseed methyl ester, does not increase the water solubility of the fuel, in particular of Diesel fuel, gasoline, and/or rapeseed methyl ester. Dated this 18th day of January, 2006. HIRAL CHANDRAKANT JOSHI AGENT FOR KOUSEMAKER, MICHIEL ARJAAN AND THIELE KLAUS DIETER

Full Text

FORM 2
THE PATENT ACT 1970 (39 of 1970)
The Patents Rules, 2003 COMPLETE SPECIFICATION (See Section 10, and rule 13)
TITLE OF INVENTION
METHOD FOR PRODUCING AN OXYGEN-CONTAINING COMPOUND USED AS FUEL ADDITIVE, IN PARTICULAR IN DIESEL FUELS, GASOLINE AND RAPESEED METHYLESTER

GRANTED
APPLICANT(S)
a) Name
b) Nationality
c) Address
AND
a) Name
b) Nationality
c) Address

KOUSEMAKER, MICHIEL ARJAAN
NETHERLANDS National
EEMS 23, 9414EE GASSELTERNIJVEEN
NETHERLANDS
THIELE, KLAUS DIETER GERMAN National TROCKENER KAMP 19, 31139 HILDESHEIM GERMANY

17-12-2007
PREAMBLE TO THE DESCRIPTION
The following specification particularly describes the invention and the manner in which it is to be performed : -
ORIGINAL

OBTECT OF THE INVENTION
The invention describes the use and production of an oxygen-containing compound in Diesel fuels, gasoline, and rapeseed methyl easter, with which the readiness for ignition is increased and the particle emission is reduced. These improvements are achieved, for example, by a) production of 2,2 dimethyl-4-hydroxymethyl-l,3 dioxolan from glycerine and acetone and b) reacting of the 2,2 dimethyl-4-hydroxymethyl,l,3 dioxolan produced in step a) with isobutane in order to etherify the remaining CH group.
DESCRIPTION OF THE PRIOR ART
The addition of oxygen compounds to fuels in the form of alcohols and ethers has proved its value. As a result of such use, it has proved possible to do away with the ecologically questionable lead compounds which served as anti-knock means in fuels. The problem therefore arose of producing a compound by the derivation of the glycerine molecule which is suitable as a fuel component.
The following compound classes are suitable compound classes which have in part already been publicised and are subject to protective rights:
Glycerine ether
Glycerine ester
Glycerine scetals
Glycerine ether

The production of glycerine ethers has been protected in a number of patent specifications. For example, the patent specification US 1 966 033 describes the etherification of multivalent alcohols. The reacting of multivalent alcohols and tertiary olefins is dealt with in terms of protective rights under DE 4 223183, A method variant for the large- scale technical production of glycerine ethers is developed in EP 649 829.
In addition to this general description for the production of glycerine ethers, special catalyst systems for use in this product class have been examined In various patent specifications. In DE 1 224 294 acidic fixed-bed catalysts are used for the reaction.
Glycerine ethers occur as a by-product in the separation of tertiary olefins from the Q fraction in the distillation of crude oil. This is dealt with in Patent Specification US 1 968 601.
In Patent Specification US 4 605 787 the production of alkyi tertiary alkyi ethers is described, whereby acidic zeolites are used as catalyst systems. The glycerine ethers are also used as phase agents in the reaction of glycerine and isobutene in DE 1 224 294.
In WO 94/01389 the production of polyalkyl ethers from polyhydroxy compounds with a high molecular weight is described.
Not only have the individual method steps for the production of glycerine ethers been dealt with in terms of patent law, but also their use as fuel components in Diesel fuels and gasoline.
It is known that the addition of oxygen-containing compounds In fuels result in an improvement in quality.

In WO 81/00721 a fuel mixture is described which has been modified by the addition of alcohols, water, ethers and vegetable oil. The Patent Specification US 4 353 710 is also concerned with the modification of Diesel fuels with ethers and esters.
The addition of ethers to Diesel fuels has been described in DE 3 140 382.
The improvement of Diesel fuel quality by the addition of aliphatic polyethers has been proven in the Patent Specification US 2 655 440. A mixture of alcohol and oxygenated hydrocarbons with a. molecular weight from 250-500 was used in Patent Specification US 4 753 661 for improving the quality of gasoline and Diesel fuel.
The invention described in US 5 308 365 relates to a Diesel qualify with low sulphur content by the addition of dialkyl and trialkyl derivatives of glycerine.
The use of these glycerine ethers is intended to serve to eliminate hydrophilicity, to incur a reduction in the boiling temperature in the range of the boiling diagram of the fuel components, and to achieve a reduction in density while maintaining the cetane number.
The disadvantage with these substances is that a glycerine-ether mixture is formed with
a maximum of 11 % oftriethers. The remainder consists of monoethers anddiethers,
which because of the hydroxyl groups still present are in part not soluble in the
individual fuel components. ' • '
Due to the steric hindrance, 100 % conversion to triethers is not possible. The conversion reaction to glycerine others is almost thermoneutral and heavily entropic. This leads to the situation that, as the temperature increases, the yield is reduced and oligomerisation sets in. With a reduction in the reaction temperature, however, the reaction is slowed to such an extant that no reaction worth mentioning takes place.

Glycerine esters
The production of glycerine esters is described in the GDR Patent Specification 156 803, This relates to the production of triacetir.
The esterisation to lower glycerine esters does indeed bring the boiling point into the range of the Diesel fuel, but with a longer acryl reside no adequate ignition behaviour is achieved. On the other hand, the boiling behaviour of the triacetin is too high and therefore excludes use in gasoline. With glycerine esters, which lie within the boiling range of the conventional fuel components, solubility in the fuels is no longer guaranteed.
The disadvantage of this substance class lies in the inadequate physical characteristics which exclude use in gasoline fuels, and the deficient ignition readiness in Diesel fuels.
Glycerine acetals
The production of glycerine acetates is described in the publications by
R.R. TinK, E.Y. Speneer, J.M. Roxburg - Cann. J. Techn. 29
243 (1951)
and
R.R. Tink; A.C. Neish - Can. J. Techn 29 243 (1951)
using the example of the reaction of glycerine with butyraldehyde.
Dioxalans with longer alkyl residues, the production of which is described by C. Diantadosi (J. Org. Chem. 80;6613 (1958)) do not come into consideration for economic reasons.

Determinant for admixture in Diesel fuel, gasoline, and rapeseed methyl ester is its solubility in these fuel components. This is very problematic due to the hydroxyl group which is present, however Even if the boiling position of the glycerine in its acetals is drastically reduced, the density in all cases is perceptibly above 1.02 g/ml.
The use of these acetals in Diesel fuel was disappointing due to its poor; ignition behaviour.
BRIEF DESCRIPTION OF THE INVENTION
Glycerine, as an extremely hydrophilic substance, cannot be mixed either with gasoline (OK) or with Diesel fuel (DK) and rapeseed methyl ester (RME). The problem is to derivatise glycerine in such a way that the products can be used as fuel components in DK,. OK, and rapeseed methyl ester- To do this, it is necessary for it to be made compatible with fuels in order to fulfil the fuel standards.
Compatibility with DK, OK, and RME is achieved by a complete reaction of the hydroxyl groups present at the glycerine molecule, on the one hand by the conversion of acetal and the etherificatlon of the hydroxyl group still present by means of a tertiary olefin.
The derivatives produced in this way can be mixed in any proportion with DK, OK, and RME.
The addition of such substances resulted in a lower particle emission and a better ignition readiness than pure DK, OK, or RME.
Example of production

In a first reaction step, for example, glycerine is reacted with acetone to 2, 2-dimethyl-4-hydroxymethyl-1, 3 dioxalan. Next, the 2,2-dimethyl-4-hydroxymethyl-l,3 dioxalan is etherified in an acidic catalyst reaction with isobutene.
Production of 2,2-dimethyl-4-hydroxymethyl-l,3 dioxalan
In a 5-litre flask 600 g of glycerine (free of water), 3600 g acetone, and 2,5 g p-toluol
sulphonic acid are mixed under powerful stirring. The reaction mixture, is stirred at room temperature and then mixed with 60 g potassium carbonate (free of water). After further stirring for about 1 hour the reaction mixture is filtrated and the filtrate distilled in fractioned form.
After a forerun of acetone, which can be used in a further reaction, distillation takes place at a pressure of 15 Torr of the 2,2-dimethyl-4-hydroxymethyl-l,3 dioxalan in a boiling range from. 82-84 °C
The yield is 550 - 600 g. According to gas chromatic testing, the substance contained a purity of > 98 % and a refraction index of n = 1,432.
Production of, 2,2-dimethyl-4-hydroxymethyl-l,3 dioxalan tert butyl ether
300 g of the 2,2-dimethyl-4-hydroxymethyl-l,3 dioxalan is presented in an autoclave with 2.5 g p-toluol sulphonic acid and cooled to -30 °C. 600 g isobutene is then added.
This mixture is brought to reaction with a magnetic stirrer at 90 °C.
After a relatively small forerun, the end product moves at 20 Torr into a boiling interval of 82-85°C.

The reactions described are repeated several times over and produce on average yields of 300 g.
According to gas chromatographic testing, with the reaction described a purity of > 95 % was obtained and a refraction index no. dependent on the purity, of 1.4190 -1.4260.
In order to obtain a purity of > 99 %, phenyl isocyanate was added to the distillate and heated under backflow. Fractioning then again took place in a vacuum. The desired product in this case was obtained, according to gas chromatographic testing, in a purity of > 99%.
The use of 2,2-dimethyl-4-hydroxymethyl-l, 3 dioxalan tert butyl ether (STBE) as a fuel
component
The substance described above was mixed as an additive to Diesel fuels, gasolines, and
rapeseed ethyl esters. In this situation we determined that the particle emission is
reduced in the form of clouding and the readiness to ignite increased in the form of dp
max.
Clouding [%] dp max bar/0
kW
6.68 8.13 5.61 6.43
2.20 1.16 1.03 0.00
Conventional commercial
Diesel fuel
Diesel fuel+ 20% STBE
RME
RME + 20 % STBE

We claim:
1. Method for producing an oxygen-containing compound used as fuel additive, in
particular in Diesel fuels, gasoline, and rapeseed methyl ester, characterised by
a) Reaction of a multivalent alcohol with an aldehyde or ketone to produce an acetal, and
b) Etherification of the still free hydroxyl groups of the acetal produced in step a) with tertiary olefins.

2. Method according to Claim 1, characterised in that the multivalent alcohol in step a) is selected from the group which comprises trivalent to hexavalent alcohols, in particular triols such as glycerine, tetrols, pentols, trimethylolpropane, penta erythrite and sugar alcohols with 4 to 6 hydroxyl groups.
3. Method according to Claim 1 or 2, characterised in that the aldehyde, the dialdehyde, or the ketone in step a) contains three to seven carbon atoms, wherein preferably acetaldehyde, acetone, or butyral aldehyde can be used.
4. Method according to one of Claims 1 to 3, characterized in that the tertiary olefin in step b) is selected from the group which comprises i-butene, 2-methyl-l-butene, 2-methyl-2-butene, isomer hexene with a tertiary carbon atom at the double bond, isomer heptene with a tertiary carbon atom at the double bond, and hydrocarbon mixtures which contain i-butene, such as in raffinate 1 of the crude oil distillation, and for preference C4 and/or C5 tert. alkenes.
5. Method according to one of Claims 1 to 4, characterised in that the raw materials for producing the oxygen-containing compound are selected in such a way that the oxygen-containing compound produced dissolves completely in the fuel, in particular in Diesel fuel, gasoline, and/or rapeseed methyl ester.
6. Method according to one of Claims 1 to 5, characterised in that the raw materials for producing the oxygen-containing compound are selected in such a way that the

addition of the oxygen-containing compound produced to the fuel, in particular to Diesel fuel, gasoline, and/or rapeseed methyl ester, does not exert a negative influence on the flash point of the fuel, in particular of the Diesel fuel, gasoline, and/or rapeseed methyl ester.
7. Method according to one of Claims 1 to 6, characterised in that the raw materials for producing the oxygen-containing compound are selected in such a way that the addition of the oxygen-containing compound produced to the fuel, in particular to Diesel fuel, gasoline, and/or rapeseed methyl ester, does not increase the water solubility of the fuel, in particular of Diesel fuel, gasoline, and/or rapeseed methyl ester.
Dated this 18th day of January, 2006.
HIRAL CHANDRAKANT JOSHI AGENT FOR
KOUSEMAKER, MICHIEL ARJAAN AND THIELE KLAUS
DIETER

Documents:

71-mumnp-2006-abstract(17-12-2007).doc

71-mumnp-2006-abstract(17-12-2007).pdf

71-MUMNP-2006-ABSTRACT(AMENDED)-(17-12-2007).pdf

71-MUMNP-2006-ABSTRACT(GRANTED)-(17-6-2008).pdf

71-mumnp-2006-cancelled pages(17-12-2007).pdf

71-MUMNP-2006-CLAIMS(AMENDED)-(17-12-2007).pdf

71-MUMNP-2006-CLAIMS(AMENDED)-(2-8-2007).pdf

71-MUMNP-2006-CLAIMS(COMPLETE)-(19-1-2006).pdf

71-mumnp-2006-claims(granted)-(17-12-2007).doc

71-mumnp-2006-claims(granted)-(17-12-2007).pdf

71-MUMNP-2006-CLAIMS(GRANTED)-(17-6-2008).pdf

71-mumnp-2006-correspondence(17-12-2007).pdf

71-MUMNP-2006-CORRESPONDENCE(IPO)-(13-10-2008).pdf

71-mumnp-2006-correspondence(ipo)-(17-06-2008).pdf

71-MUMNP-2006-DESCRIPTION(COMPLETE)-(19-1-2006).pdf

71-MUMNP-2006-DESCRIPTION(GRANTED)-(17-6-2008).pdf

71-mumnp-2006-form 1(19-01-2006).pdf

71-mumnp-2006-form 18(23-01-2006).pdf

71-MUMNP-2006-FORM 2(COMPLETE)-(19-1-2006).pdf

71-mumnp-2006-form 2(granted)-(17-12-2007).doc

71-mumnp-2006-form 2(granted)-(17-12-2007).pdf

71-MUMNP-2006-FORM 2(GRANTED)-(17-6-2008).pdf

71-MUMNP-2006-FORM 2(TITLE PAGE)-(COMPLETE)-(19-1-2006).pdf

71-MUMNP-2006-FORM 2(TITLE PAGE)-(GRANTED)-(17-6-2008).pdf

71-mumnp-2006-form 3(19-01-2006).pdf

71-mumnp-2006-form 5(19-01-2006).pdf

71-mumnp-2006-form-pct-isa-210(19-01-2006).pdf

71-MUMNP-2006-GENERAL POWER OF ATTORNEY(15-5-2006).pdf

71-mumnp-2006-other(02-08-2007).pdf

71-mumnp-2006-power of attorney(19-01-2006).pdf

71-mumnp-2006-power of attorney(27-04-2006).pdf

71-MUMNP-2006-SPECIFICATION(AMENDED)-(19-1-2006).pdf

71-MUMNP-2006-WO INTERNATIONAL PUBLICATION REPORT(19-1-2006).pdf

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Patent Number

221091

Indian Patent Application Number

71/MUMNP/2006

PG Journal Number

35/2008

Publication Date

29-Aug-2008

Grant Date

17-Jun-2008

Date of Filing

19-Jan-2006

Name of Patentee

THIELE, KLAUS DIETER

Applicant Address

TROCKENER KAMP 19, 31139 HILDESHEIM GERMANY.

Inventors:

#	Inventor's Name	Inventor's Address
1	KOUSEMAKER, MICHIEL ARJAAN	EEMS 23, 9414 EE GASSELTERNIJVEEN NETHERLANDS.
2	THIELE, KLAUS DIETER	TROCKENER KAMP 19 31139 HILDESHEIM GERMANY.

PCT International Classification Number

C 10 L 1/18

PCT International Application Number

PCT/DE04/000999

PCT International Filing date

2004-05-13

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	103 28 159.2	2003-06-24	Germany