Title of Invention	PROCESS FOR THE PRODUCTION OF BIS (SILYLORGANYL)POLYSULPHANES
Abstract	This invention relates to a process for the production of bis(silylorganyl)polysulphanes of the general formula (R1R2R3SiR4)2Sx (I) in which R1 , R2 , R3 : mean identically or differently from each other, branched and unbranched alkyl and/or is [sic] aryl residues, in particular phenyl, toluyl, benzyl; R4 : means a divalent alkylidene residue having a chain length of 1-8 C atoms, or -(CH2)n-C6H4-(CH2)n- (n= 1 to 4); by reacting haloalkylalkoxysilanes or haloalkoxysilanes of the general formula R1R2R3SiR4x (II) with a polysulphide of the general formula M2SX (III), which process is characterised in that in a first stage dehydrated polysulphides are obtained by reacting a sulphide hydrate containing water of crystallisation with sulphur under a vacuum at a temperature of 60 to 300°C.

Title of Invention

PROCESS FOR THE PRODUCTION OF BIS (SILYLORGANYL)POLYSULPHANES

Abstract

This invention relates to a process for the production of bis(silylorganyl)polysulphanes of the general formula (R1R2R3SiR4)2Sx (I) in which R1 , R2 , R3 : mean identically or differently from each other, branched and unbranched alkyl and/or is [sic] aryl residues, in particular phenyl, toluyl, benzyl; R4 : means a divalent alkylidene residue having a chain length of 1-8 C atoms, or -(CH2)n-C6H4-(CH2)n- (n= 1 to 4); by reacting haloalkylalkoxysilanes or haloalkoxysilanes of the general formula R1R2R3SiR4x (II) with a polysulphide of the general formula M2SX (III), which process is characterised in that in a first stage dehydrated polysulphides are obtained by reacting a sulphide hydrate containing water of crystallisation with sulphur under a vacuum at a temperature of 60 to 300°C.

Full Text	960119 SO 2 Process for the production of bis(silylorganyl)-polysulphanes This invention relates to a process for the production of polysulphide silanes using an inoraanic polvsulohide produced in a novel manner. The use of bis(triethoxysilylpropyl)tetrasulphane combined with silicas having an elevated surface area in order to improve the properties of automotive tyres, such as abrasion, wet skidding resistance and rolling resistance is prior art which has been documented in numerous patent applications. The difunctional silane here acts as a bridge between the hydrophilic inorganic filler, silica, and the hydrophobic organic polymer, wherein a strong covalent bond is formed between the filler and the polymer. The silylalkylpolysulphanes are essentially produced by nucleophilic substitution on chloroalkylsilanes with anionic polysulphides produced in various manners. This process was first described in patent DE-PS 2141159, but this document gives no information relating to the production of the nucleophilic polysulphide. However, production of the nucleophilic polysulphide is the critical part of the process which gives rise to silylalkylpolysulphanes . Some patents have described the use of hydrogen sulphides to produce the precursor polysulphide. The patent DE-PS 2542534 accordingly proposes a method for the production of bis(silylalkyl)polysulphanes in which the polysulphide is formed in situ from hydrogen sulphide and sulphur in alcohol. Hydrogen sulphide is liberated in this process and must be disposed of by suitable measures. This disposal entails additional, economically undesirable, capital costs for an industrial plant. While liberation of hydrogen 960119 SO 3- sulphide may indeed be suppressed by adding alkoxides {patent DE-PS 2712866 and DE-OS 3311340), this approach is disadvantageous for technical and economic reasons. Firstly, the anhydrous hydrogen sulphide required for performance of this process must be obtained in a preceding process stage, for example by a reaction between alkoxides and hydrogen sulphide (c.f. US patent 5399739). Hydrogen sulphide, being a highly toxic gas, constitutes a considerable safety hazard, which must be minimised at some cost by suitable technical measures. Furthermore, most alkoxides have only limited storage stability, so entailing continuous in situ production. This additional starting product thus considerably increases the production costs of the desired bis(silylalkyl)polysulphanes. One possibility for producing the nucleophilic polysulphide is to react sulphide with sulphur. US patents 5405985 and 5468893 and application EP-A 694552 propose processes which obtain the corresponding polysulphide in an aqueous solution from sulphides and sulphur and react it with haloalkylsilanes in a two-phase system by phase transfer catalysis to yield polysulphanes. In this method, the phase transfer catalyst remains in the product so exerting an as yet unexplained influence on the applicational properties of the bis(silylalkyl)polysulphanes. Furthermore, due to the known susceptibility to hydrolysis of the alkoxysilanes used, the products are distinguished, as may be expected, by poor storage stability, so further restricting the customer's processing options. For these reasons, two-phase synthesis with a polysulphide produced in an aqueous solution is clearly not an acceptable approach. There are thus reasons for using anhydrous polysulphide for the reaction between inorganic polysulphide and 960119 SO 4 alkoxysilane. The problem then arises that anhydrous sulphides are not commercially available. Japanese published patent application JP 7-228588 proposes two processes for the production of a polysulphide to solve this problem. In the first process, a hydrous sodium sulphide is dissolved in a solvent mixture and the water of crystallisation present therein is removed by azeotropic distillation of the solvent. In the second method, once drying has been performed under a vacuum, the sodium sulphide is reacted with sulphur in anhydrous ethanol. Very long reaction times of 5 h are required for synthesis of polysulphides from sulphides and sulphur in boiling alcohol. This is substantially because sodium sulphide and sulphur have only very limited solubility in the solvents used. Diffusion of the two reactants towards each other thus becomes a determining factor for the rate of reaction. Were the proposed process scaled up to the industrial scale, it is to be suspected that this reaction time would be still longer. However, with regard to increasing the space/time yield and thus to ensuring better utilisation of capital investment, it is necessary to shorten the reaction time in order to achieve an economically viable reaction. The sodium polysulphide is furthermore obtained in the form of alcoholic solutions/dispersions. This proves to be very disadvantageous if further processing and production are not performed on the same site. The present invention proposes a process, superior to the prior art, to solve this problem which yields a dehydrated, solid product with shorter reaction times. 960119 SO 5 The present invention provides a process for the production of bis(silylorganyl)polysulphanes of the general formula (R1R2R3SiR4)2Sx (I) in which R1 , R2 , R3 : mean identically or differently from each other, branched and unbranched alkyl and/or alkoxy groups having a chain length of 1-8 C atoms, wherein at least one alkoxy group is present, aryl residues, in particular phenyl, toluyl, benzyl; R4 : means a divalent alkylidene residue having a chain length of 1-8 C atoms, preferably 1 to 4 C atoms or -(CH2)n-C6H4-(CH2)n- (n= 1 to 4); x means a number >1, preferably from 2 to 8, in particular from 2 to 6, by reacting haloalkyl alkoxysilanes or haloalkoxysilanes of the general formula R1R2R3SiR4X (II) in which R1, R2, R3 R4 have the meaning from the formula (I) and X designates a halogen atom such as Cl, Br or I, with a polysulphide of the general formula M2SX (III), wherein M denotes an alkali metal cation, half an alkaline earth metal or zinc cation and x denotes a number from 2 to 8, in particular from 2 to 6, which process is characterised in that in a first stage dehydrated polysulphides according to the formula (III) are obtained by reacting sulphides, containing 960119 SO 6 water of crystallisation (sulphide hydrates) of the general formula M2SX-z (IV) in which M and x have the meanings as above, z designates a number from 1 to 7 and (x-z) is >1, with sulphur in the absence of an organic solvent under a vacuum at a temperature of 60 to 300°C. Suitable educts for the dehydrated polysulphides are any inorganic sulphides containing water of crystallisation, preferably a sodium sulphide. This substance is in particular offered for sale commercially with an Na2S content of 60-62% and is particularly suitable in this form as a raw material for the process according to the invention. The temperatures and pressures necessary for dehydration and simultaneous polysulphide production are not critical to the performance of the invention, provided that they are adequate to dehydrate the sulphide used. In general, temperatures of 60-300°C at a vacuum of between 0.6-102 and 70-102 Pa are adequate. At temperatures above the phase transition temperature of the sulphide used, the sulphide initially dissolves in the liberated water of crystallisation, which is perceived as "melting" of the material. As dehydration proceeds, solid polysulphides or a mixture of polysulphides are obtained, in which the average length of the polysulphane chain assumes a value of >1 to 8, which adheres to the dryer walls and must thus be removed mechanically. In a preferred embodiment of the invention, this "melting operation" is avoided by using temperatures of below the phase transition temperature. As dehydration proceeds, the temperature may gradually be 960119 SO 7 increased as the phase transition temperature rises due to the falling content of water of crystallisation, until a dehydrated polysulphide is obtained. The vacuum required for performance of the invention is temperature-dependent. The higher is the selected temperature, the higher are the admissible pressures. It is appropriate, in order to shorten the dehydration/synthesis time, to use the lowest possible pressures. In a preferred embodiment of the invention, a vacuum of 40 -102 Pa is used. The ratio of sulphide hydrate to S may be selected such that a wide range of polysulphides M2SX is covered. One equivalent of sulphide hydrate and n(x-l) equivalents of sulphur are required for a desired polysulphide M2SX. According to the invention, the factor n may vary between stoichiometric quantities of sulphur (n = 1) and a slight excess or deficit of sulphur {1 1), between 2 and 8 S atoms (2 The polysulphide according to the formula (III) produced in the combined dehydration and synthesis stage is then reacted with halosilanes according to the formula (II) in an inert polar solvent or solvent mixture. The reaction components halosilane according to the formula (II) and the polysulphides according to the formula (III) may be introduced together into a solvent or solvent mixture and reacted, or one of the two reactants is apportioned as such or as a solution to the second reaction component. The second reaction component may also be 960119 SO 8 present as the substance or as a solution. It is not critical to performance of the process according to the invention which of the two reactants is initially introduced and which is apportioned. The polysulphide production (characterising clause from claim 1) which precedes the actual production of the bis(silylorganyl)polysulphides results in a considerable shortening of cycle times and makes this process particularly economic. In a preferred embodiment of the invention, both reactants according to the formulae (II) and (III) are initially introduced into an inert solvent or solvent mixture and then reacted. Solvents or components of a solvent mixture which may be considered are ethers such as diethyl ether, diisopropyl ether, dibutyl ether, methyl tert.-butyl ether, tetrahydrofuran, dioxane, dimethoxyethane or diethoxyethane, alcohols such as methanol, ethanol, propanol and ethylene glycol together with aliphatic or aromatic hydrocarbons such as pentane, hexane, heptane, petroleum ether, benzene, toluene or xylene. Preferred solvents are alcohols, wherein in a particularly preferred embodiment of the invention, the alcohol used corresponds to that of the alkoxy group attached to the alkoxysilyl group. The reaction solution is heated to a temperature of between 40°C and the boiling point of the reaction mixture in order to accelerate the reaction between the chloroalkylsilane and the polysulphides. A reaction temperature close to the boiling point of the reaction mixture is preferably used. 960119 SO 9 The pressure prevailing during the reaction is not critical to performance of this invention, provided that it allows reaction temperatures of above 40°C. Reaction time is dependent upon reaction temperature. The higher is the reaction temperature, the shorter is the time required for completion of the reaction. Reaction times of 1 to 8 h are generally sufficient. Once the reaction is complete, the reaction mixture is filtered in order to remove the precipitated insoluble halides. The solvent or solvent mixture is separated from the filtrate. To this end, the product mixture is heated to a temperature above the boiling temperature of the solvent or solvent mixture, which is distilled off. In a preferred embodiment, the solvent is removed under a vacuum. The following Examples illustrate performance of the invention in greater detail. 960119 SO -10- Example 1: Production of bis(3,3'-triethoxysilylpropyl)polysulphane having an average S chain length of 3.7 32.04 g (approx. 0.25 mol) of Na2S hydrate (Na2S content 60-62%) are introduced together with 24.05 g (0.75 mol) of sulphur into a 500 ml 3-necked flask fitted with a reflux condenser and heated to 250°C in a heating mantle under a vacuum of 35 mbar for 1.5 h. The mixture first melts and water is distilled off. After 1.5 h, the melt has solidified. The temperature is reduced, the flask provided with a dropping funnel, N2 purging and a KPG stirrer and charged with 125 ml of ethanol. After heating to reflux, wherein a proportion of the solidified melt passes into solution, 120.4 g (0.5 mol) of 3-chloropropyltriethoxy-silane are added dropwise at this temperature within 15 minutes. Refluxing is continued for a further 2 h, wherein the colour of the reaction mixture changes from the original dark brown to yellow. After cooling at room temperature, the mixture is pressure-filtered, the filter cake rinsed with 50 ml [sic] and the combined filtrates evaporated in a rotary evaporator at 90°C and 30 mbar. 121.51 g (0.23 mol) of a polysulphane mixture having an average S chain length of 3.7 are obtained. Yield is 92%. The identity of the mixture is confirmed by the 1H-NMR spectrum. Example 2: 960119 SO 11 Production of bis (3,3'triethoxysilylpropyl)polysulphane having an average S chain length of 3.7 32.04 g (approx. 0.25 mol) of Na2S hydrate (60-62% Na2S) are introduced together with 24.05 g (0.75 mol) of sulphur into a notched 1000 ml flask and, under a vacuum of 13 mbar, exposed to the following temperature programme in a rotary evaporator: 15 min 90°C 30 min 100°C 30 min 110°C 60 min 140°C The resultant sodium polysulphide, which did not melt during dehydration, is transferred into a three-necked flask. After addition of 125 ml of ethanol and 120.4 g of 3-chloropropyltriethoxysilane, the mixture is refluxed for 2 h in a 500 ml three-necked flask provided with a reflux condenser and N2 purging. The temperature is reduced to room temperature, the precipitate filtered out and the filter cake washed with 50 ml of ethanol. Once the solvent has been distilled off from the combined filtrates in a rotary evaporator at 90°C and a vacuum of 30 mbar, a little precipitate must again be filtered out. 120.90 g (0.23 mol) of a polysulphane mixture having an average S chain length of 3.7 are obtained. Yield is 92%. The identity of the mixture is proven by the 1H-NMR spectrum. Example 3: Production of bis (3,3'triethoxysilylpropyl)polysulphane having an average S chain length of 2.0 960119 SO 12 32.04g (approx. 0.25 mol) of Na2S hydrate (Na2S content 60-62%) are introduced together with 8.02 g (0.25 mol) of sulphur into the apparatus of Example 1 and heated to 250°C in a heating mantle for 2 h under a vacuum of 35 mbar. The mixture first melts and water is distilled off. After 2 h, the mixture has solidified. The temperature is reduced, the flask provided with a dropping funnel and a KPG stirrer and charged with 125 ml of ethanol. After heating to reflux, wherein a proportion of the solidified melt passes into solution, 120.4 g (0.5 mol) of 3-chloropropyltriethoxy-silane are added dropwise at this temperature within 15 minutes. Refluxing is continued for a further 2 h, wherein the colour of the reaction mixture changes from the original orange-yellow to yellow. After cooling at room temperature, the mixture is pressure-filtered, the filter cake rinsed with 50 ml of ethanol and the combined filtrates evaporated in a rotary evaporator at 90°C and 30 mbar. 99.51 g (0.21 mol) of a polysulphane mixture having an average S chain length of 2.0 are obtained. Yield is 84%. The identity of the mixture is confirmed by the 1H-NMR spectrum. Example 4: Production of bis(3,3'triethoxysilylpropyl)polysulphane having an average S chain length of 1.9 32.04 g (approx. 0.25 mol) of Na2S hydrate (60-62% Na2S) are introduced together with 8.02 g (0.25 g) of sulphur into the same apparatus as in Example 2 and, under a vacuum of 13 mbar, exposed to the following temperature programme in a rotary evaporator: 15 min 90°C 30 min 100°C 960119 SO 13 30 min 110°C 60 min 140°C The resultant sodium polysulphide, which did not melt during dehydration, is transferred into a three-necked flask. After addition of 125 ml of ethanol and 120.4 g of 3-chloropropyltriethoxysilane, the mixture is refluxed for 2 h in a 500 ml three-necked flask provided with a reflux condenser and N2 purging. The temperature is reduced to room temperature, the precipitate filtered out and the filter cake washed with 50 ml of ethanol. Once the solvent has been distilled off from the combined filtrates in a rotary evaporator at 90°C and a vacuum of 30 mbar, a little precipitate must again be filtered out. 97.45 g (0.21 mol) of a polysulphane mixture having an average S chain length of 1.9 are obtained. Yield is 83%. The identity of the mixture is proven by the 1H-NMR spectrum. 960119 SO 14 Process for the production of bis(silylorganyl)- polysulphanes WE CLAIMS 1. Process for the production of bis (silylorganyl)-polysulphanes of the general formula (R1R2R3SiR4)2Sx (I) in which R1, R2, R3: mean identically or differently from each other, branched and unbranched alkyl and/or alkoxy groups having a chain length of 1-8 C atoms, wherein at least one alkoxy group is present, aryl residues, in particular phenyl, toluyl, benzyl; R4 : means a divalent alkylidene residue having a chain length of 1-8 C atoms, preferably 1 to 4 C atoms or -(CH2)n-C6H4-(CH2)n- (n= 1 to 4); x means a number >1, preferably from 2 to 8; by reacting haloalkylalkoxysilanes or haloalkoxysilanes of the general formula R1R2R3SiR4X (II) in which R1, R2, R3 R4 have the meaning from the formula (I) and X designates a halogen atom such as Cl, Br or I, with a polysulphide of the general formula M2SX (III), wherein M denotes an alkali metal cation, half an 960119 SO 15 alkaline earth metal or zinc cation and x denotes a number from 2 to 8, characterised in that in a first stage dehydrated polysulphides according to the formula (III) are obtained by reacting sulphides containing water of crystallisation (sulphide hydrates) of the general formula M2SX-Z (IV) in which M and x have the meanings as above, z designates a number from 1 to 7 and (x-z) is >1, with sulphur in the absence of an organic solvent under a vacuum at a temperature of 60 to 300°C. 2. Process according to claim 1, characterised in that , in the first stage Na2S containing water of crystallisation having an Na2S content of 60 to 62 wt.% is used. 3. Process according to claims 1 and 2 characterised in that , a vacuum of between 0.6-10 and 70-10 Pa is used. 4. Process according to claims 1 or 3, characterised in that, in order to produce a polysulphide of the general formula (III), one equivalent of the hydrated monosulphide is reacted with n(x-l) equivalents of sulphur, wherein n assumes a value of 1 5. Process according to claims 1 to 4, characterised in that the temperature during the reaction to yield the polysulphides is increased as a function of the phase transition temperature of the -16- sulphide hydrates in such a manner that it is always below the particular relevant transition temperature. Dated this 9th day of December 1997. This invention relates to a process for the production of bis(silylorganyl)polysulphanes of the general formula (R1R2R3SiR4)2Sx (I) in which R1 , R2 , R3 : mean identically or differently from each other, branched and unbranched alkyl and/or is [sic] aryl residues, in particular phenyl, toluyl, benzyl; R4 : means a divalent alkylidene residue having a chain length of 1-8 C atoms, or -(CH2)n-C6H4-(CH2)n- (n= 1 to 4); by reacting haloalkylalkoxysilanes or haloalkoxysilanes of the general formula R1R2R3SiR4x (II) with a polysulphide of the general formula M2SX (III), which process is characterised in that in a first stage dehydrated polysulphides are obtained by reacting a sulphide hydrate containing water of crystallisation with sulphur under a vacuum at a temperature of 60 to 300°C.

Full Text

960119 SO
2
Process for the production of bis(silylorganyl)-polysulphanes
This invention relates to a process for the production of polysulphide silanes using an inoraanic polvsulohide produced in a novel manner.
The use of bis(triethoxysilylpropyl)tetrasulphane combined with silicas having an elevated surface area in order to improve the properties of automotive tyres, such as abrasion, wet skidding resistance and rolling resistance is prior art which has been documented in numerous patent applications. The difunctional silane here acts as a bridge between the hydrophilic inorganic filler, silica, and the hydrophobic organic polymer, wherein a strong covalent bond is formed between the filler and the polymer.
The silylalkylpolysulphanes are essentially produced by nucleophilic substitution on chloroalkylsilanes with anionic polysulphides produced in various manners. This process was first described in patent DE-PS 2141159, but this document gives no information relating to the production of the nucleophilic polysulphide. However, production of the nucleophilic polysulphide is the critical part of the process which gives rise to silylalkylpolysulphanes .
Some patents have described the use of hydrogen sulphides to produce the precursor polysulphide. The patent DE-PS 2542534 accordingly proposes a method for the production of bis(silylalkyl)polysulphanes in which the polysulphide is formed in situ from hydrogen sulphide and sulphur in alcohol. Hydrogen sulphide is liberated in this process and must be disposed of by suitable measures. This disposal entails additional, economically undesirable, capital costs for an industrial plant. While liberation of hydrogen

960119 SO
3-
sulphide may indeed be suppressed by adding alkoxides {patent DE-PS 2712866 and DE-OS 3311340), this approach is disadvantageous for technical and economic reasons.
Firstly, the anhydrous hydrogen sulphide required for performance of this process must be obtained in a preceding process stage, for example by a reaction between alkoxides and hydrogen sulphide (c.f. US patent 5399739). Hydrogen sulphide, being a highly toxic gas, constitutes a considerable safety hazard, which must be minimised at some cost by suitable technical measures. Furthermore, most alkoxides have only limited storage stability, so entailing continuous in situ production. This additional starting product thus considerably increases the production costs of the desired bis(silylalkyl)polysulphanes.
One possibility for producing the nucleophilic polysulphide is to react sulphide with sulphur. US patents 5405985 and 5468893 and application EP-A 694552 propose processes which obtain the corresponding polysulphide in an aqueous solution from sulphides and sulphur and react it with haloalkylsilanes in a two-phase system by phase transfer catalysis to yield polysulphanes. In this method, the phase transfer catalyst remains in the product so exerting an as yet unexplained influence on the applicational properties of the bis(silylalkyl)polysulphanes. Furthermore, due to the known susceptibility to hydrolysis of the alkoxysilanes used, the products are distinguished, as may be expected, by poor storage stability, so further restricting the customer's processing options. For these reasons, two-phase synthesis with a polysulphide produced in an aqueous solution is clearly not an acceptable approach.
There are thus reasons for using anhydrous polysulphide for the reaction between inorganic polysulphide and

960119 SO
4
alkoxysilane.
The problem then arises that anhydrous sulphides are not
commercially available.
Japanese published patent application JP 7-228588 proposes two processes for the production of a polysulphide to solve this problem. In the first process, a hydrous sodium sulphide is dissolved in a solvent mixture and the water of crystallisation present therein is removed by azeotropic distillation of the solvent. In the second method, once drying has been performed under a vacuum, the sodium sulphide is reacted with sulphur in anhydrous ethanol.
Very long reaction times of 5 h are required for synthesis of polysulphides from sulphides and sulphur in boiling alcohol. This is substantially because sodium sulphide and sulphur have only very limited solubility in the solvents used. Diffusion of the two reactants towards each other thus becomes a determining factor for the rate of reaction. Were the proposed process scaled up to the industrial scale, it is to be suspected that this reaction time would be still longer.
However, with regard to increasing the space/time yield and thus to ensuring better utilisation of capital investment, it is necessary to shorten the reaction time in order to achieve an economically viable reaction. The sodium polysulphide is furthermore obtained in the form of alcoholic solutions/dispersions. This proves to be very disadvantageous if further processing and production are not performed on the same site.
The present invention proposes a process, superior to the prior art, to solve this problem which yields a dehydrated, solid product with shorter reaction times.

960119 SO
5
The present invention provides a process for the production
of bis(silylorganyl)polysulphanes of the general formula
(R1R2R3SiR4)2Sx (I)
in which

R1 , R2 , R3 : mean identically or differently from each
other, branched and unbranched alkyl and/or alkoxy groups having a chain length of 1-8 C atoms, wherein at least one alkoxy group is present, aryl residues, in particular phenyl, toluyl, benzyl;
R4 : means a divalent alkylidene residue having a chain length of 1-8 C atoms, preferably 1 to 4 C atoms or -(CH2)n-C6H4-(CH2)n- (n= 1 to 4);
x means a number >1, preferably from 2 to 8, in
particular from 2 to 6, by reacting haloalkyl
alkoxysilanes or haloalkoxysilanes of the
general formula
R1R2R3SiR4X (II)
in which
R1, R2, R3 R4 have the meaning from the formula (I)
and
X designates a halogen atom such as Cl, Br or
I, with a polysulphide of the general formula
M2SX (III),
wherein
M denotes an alkali metal cation, half an
alkaline earth metal or zinc cation and
x denotes a number from 2 to 8, in particular
from 2 to 6, which process is characterised in that in a first stage dehydrated polysulphides according to the formula (III) are obtained by reacting sulphides, containing

960119 SO
6
water of crystallisation (sulphide hydrates) of the general
formula
M2SX-z (IV)
in which M and x have the meanings as above, z designates a number from 1 to 7 and (x-z) is >1, with sulphur in the absence of an organic solvent under a vacuum at a
temperature of 60 to 300°C.
Suitable educts for the dehydrated polysulphides are any inorganic sulphides containing water of crystallisation, preferably a sodium sulphide.
This substance is in particular offered for sale commercially with an Na2S content of 60-62% and is particularly suitable in this form as a raw material for the process according to the invention.
The temperatures and pressures necessary for dehydration and simultaneous polysulphide production are not critical to the performance of the invention, provided that they are adequate to dehydrate the sulphide used. In general, temperatures of 60-300°C at a vacuum of between 0.6-102 and 70-102 Pa are adequate. At temperatures above the phase transition temperature of the sulphide used, the sulphide initially dissolves in the liberated water of crystallisation, which is perceived as "melting" of the material. As dehydration proceeds, solid polysulphides or a mixture of polysulphides are obtained, in which the average length of the polysulphane chain assumes a value of >1 to 8, which adheres to the dryer walls and must thus be removed mechanically. In a preferred embodiment of the invention, this "melting operation" is avoided by using temperatures of below the phase transition temperature. As dehydration proceeds, the temperature may gradually be

960119 SO
7
increased as the phase transition temperature rises due to the falling content of water of crystallisation, until a dehydrated polysulphide is obtained.
The vacuum required for performance of the invention is temperature-dependent. The higher is the selected temperature, the higher are the admissible pressures. It is appropriate, in order to shorten the dehydration/synthesis time, to use the lowest possible pressures. In a preferred embodiment of the invention, a vacuum of 40 -102 Pa is used.
The ratio of sulphide hydrate to S may be selected such that a wide range of polysulphides M2SX is covered. One equivalent of sulphide hydrate and n(x-l) equivalents of sulphur are required for a desired polysulphide M2SX. According to the invention, the factor n may vary between stoichiometric quantities of sulphur (n = 1) and a slight excess or deficit of sulphur {1 1), between 2 and 8 S atoms (2 The polysulphide according to the formula (III) produced in the combined dehydration and synthesis stage is then reacted with halosilanes according to the formula (II) in an inert polar solvent or solvent mixture.
The reaction components halosilane according to the formula (II) and the polysulphides according to the formula (III) may be introduced together into a solvent or solvent mixture and reacted, or one of the two reactants is apportioned as such or as a solution to the second reaction component. The second reaction component may also be

960119 SO
8
present as the substance or as a solution. It is not critical to performance of the process according to the invention which of the two reactants is initially introduced and which is apportioned.
The polysulphide production (characterising clause from claim 1) which precedes the actual production of the bis(silylorganyl)polysulphides results in a considerable shortening of cycle times and makes this process particularly economic.
In a preferred embodiment of the invention, both reactants according to the formulae (II) and (III) are initially introduced into an inert solvent or solvent mixture and then reacted.
Solvents or components of a solvent mixture which may be considered are ethers such as diethyl ether, diisopropyl ether, dibutyl ether, methyl tert.-butyl ether, tetrahydrofuran, dioxane, dimethoxyethane or diethoxyethane, alcohols such as methanol, ethanol, propanol and ethylene glycol together with aliphatic or aromatic hydrocarbons such as pentane, hexane, heptane, petroleum ether, benzene, toluene or xylene. Preferred solvents are alcohols, wherein in a particularly preferred embodiment of the invention, the alcohol used corresponds to that of the alkoxy group attached to the alkoxysilyl group.
The reaction solution is heated to a temperature of between 40°C and the boiling point of the reaction mixture in order to accelerate the reaction between the chloroalkylsilane and the polysulphides. A reaction temperature close to the boiling point of the reaction mixture is preferably used.

960119 SO
9
The pressure prevailing during the reaction is not critical to performance of this invention, provided that it allows reaction temperatures of above 40°C.
Reaction time is dependent upon reaction temperature. The higher is the reaction temperature, the shorter is the time required for completion of the reaction. Reaction times of 1 to 8 h are generally sufficient.
Once the reaction is complete, the reaction mixture is filtered in order to remove the precipitated insoluble halides. The solvent or solvent mixture is separated from the filtrate. To this end, the product mixture is heated to a temperature above the boiling temperature of the solvent or solvent mixture, which is distilled off. In a preferred embodiment, the solvent is removed under a vacuum.
The following Examples illustrate performance of the invention in greater detail.

960119 SO
-10-
Example 1:
Production of bis(3,3'-triethoxysilylpropyl)polysulphane
having an average S chain length of 3.7
32.04 g (approx. 0.25 mol) of Na2S hydrate (Na2S content 60-62%) are introduced together with 24.05 g (0.75 mol) of sulphur into a 500 ml 3-necked flask fitted with a reflux
condenser and heated to 250°C in a heating mantle under a vacuum of 35 mbar for 1.5 h. The mixture first melts and water is distilled off. After 1.5 h, the melt has solidified. The temperature is reduced, the flask provided with a dropping funnel, N2 purging and a KPG stirrer and charged with 125 ml of ethanol. After heating to reflux, wherein a proportion of the solidified melt passes into solution, 120.4 g (0.5 mol) of 3-chloropropyltriethoxy-silane are added dropwise at this temperature within 15 minutes. Refluxing is continued for a further 2 h, wherein the colour of the reaction mixture changes from the original dark brown to yellow. After cooling at room temperature, the mixture is pressure-filtered, the filter cake rinsed with 50 ml [sic] and the combined filtrates evaporated in a rotary evaporator at 90°C and 30 mbar. 121.51 g (0.23 mol) of a polysulphane mixture having an average S chain length of 3.7 are obtained. Yield is 92%. The identity of the mixture is confirmed by the 1H-NMR spectrum.
Example 2:

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11
Production of bis (3,3'triethoxysilylpropyl)polysulphane having an average S chain length of 3.7
32.04 g (approx. 0.25 mol) of Na2S hydrate (60-62% Na2S) are introduced together with 24.05 g (0.75 mol) of sulphur into a notched 1000 ml flask and, under a vacuum of 13 mbar, exposed to the following temperature programme in a rotary evaporator:
15 min 90°C
30 min 100°C
30 min 110°C
60 min 140°C
The resultant sodium polysulphide, which did not melt during dehydration, is transferred into a three-necked flask. After addition of 125 ml of ethanol and 120.4 g of 3-chloropropyltriethoxysilane, the mixture is refluxed for 2 h in a 500 ml three-necked flask provided with a reflux condenser and N2 purging. The temperature is reduced to room temperature, the precipitate filtered out and the filter cake washed with 50 ml of ethanol. Once the solvent has been distilled off from the combined filtrates in a rotary evaporator at 90°C and a vacuum of 30 mbar, a little precipitate must again be filtered out. 120.90 g (0.23 mol) of a polysulphane mixture having an average S chain length of 3.7 are obtained. Yield is 92%. The identity of the mixture is proven by the 1H-NMR spectrum.
Example 3:
Production of bis (3,3'triethoxysilylpropyl)polysulphane
having an average S chain length of 2.0

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12
32.04g (approx. 0.25 mol) of Na2S hydrate (Na2S content 60-62%) are introduced together with 8.02 g (0.25 mol) of sulphur into the apparatus of Example 1 and heated to 250°C in a heating mantle for 2 h under a vacuum of 35 mbar. The mixture first melts and water is distilled off. After 2 h, the mixture has solidified. The temperature is reduced, the flask provided with a dropping funnel and a KPG stirrer and charged with 125 ml of ethanol. After heating to reflux, wherein a proportion of the solidified melt passes into solution, 120.4 g (0.5 mol) of 3-chloropropyltriethoxy-silane are added dropwise at this temperature within 15 minutes. Refluxing is continued for a further 2 h, wherein the colour of the reaction mixture changes from the original orange-yellow to yellow. After cooling at room temperature, the mixture is pressure-filtered, the filter cake rinsed with 50 ml of ethanol and the combined filtrates evaporated in a rotary evaporator at 90°C and 30 mbar. 99.51 g (0.21 mol) of a polysulphane mixture having an average S chain length of 2.0 are obtained. Yield is 84%. The identity of the mixture is confirmed by the 1H-NMR spectrum.
Example 4:
Production of bis(3,3'triethoxysilylpropyl)polysulphane
having an average S chain length of 1.9
32.04 g (approx. 0.25 mol) of Na2S hydrate (60-62% Na2S) are introduced together with 8.02 g (0.25 g) of sulphur into the same apparatus as in Example 2 and, under a vacuum of 13 mbar, exposed to the following temperature programme in a rotary evaporator:
15 min 90°C
30 min 100°C

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13
30 min 110°C
60 min 140°C
The resultant sodium polysulphide, which did not melt during dehydration, is transferred into a three-necked flask. After addition of 125 ml of ethanol and 120.4 g of 3-chloropropyltriethoxysilane, the mixture is refluxed for 2 h in a 500 ml three-necked flask provided with a reflux condenser and N2 purging. The temperature is reduced to room temperature, the precipitate filtered out and the filter cake washed with 50 ml of ethanol. Once the solvent has been distilled off from the combined filtrates in a
rotary evaporator at 90°C and a vacuum of 30 mbar, a little precipitate must again be filtered out. 97.45 g (0.21 mol) of a polysulphane mixture having an average S chain length of 1.9 are obtained. Yield is 83%. The identity of the mixture is proven by the 1H-NMR spectrum.

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14
Process for the production of bis(silylorganyl)-
polysulphanes
WE CLAIMS
1. Process for the production of bis (silylorganyl)-polysulphanes of the general formula
(R1R2R3SiR4)2Sx (I)
in which R1, R2, R3: mean identically or differently from
each other, branched and unbranched alkyl and/or alkoxy groups having a chain length of 1-8 C atoms, wherein at least one alkoxy group is present, aryl residues, in particular phenyl, toluyl, benzyl; R4 : means a divalent alkylidene residue having a chain length of 1-8 C atoms, preferably 1 to 4 C atoms or
-(CH2)n-C6H4-(CH2)n- (n= 1 to 4);
x means a number >1, preferably from 2 to 8;
by reacting haloalkylalkoxysilanes or
haloalkoxysilanes of the general formula
R1R2R3SiR4X (II)
in which R1, R2, R3 R4 have the meaning from the formula (I)
and
X designates a halogen atom such as Cl,
Br or I, with a polysulphide of the general formula
M2SX (III),
wherein
M denotes an alkali metal cation, half an

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15
alkaline earth metal or zinc cation and
x denotes a number from 2 to 8,
characterised in that in a first stage dehydrated polysulphides according to the formula (III) are obtained by reacting sulphides containing water of crystallisation (sulphide hydrates) of the general formula
M2SX-Z (IV)
in which M and x have the meanings as above, z designates a number from 1 to 7 and (x-z) is >1, with sulphur in the absence of an organic solvent under a
vacuum at a temperature of 60 to 300°C.
2. Process according to claim 1,
characterised in that ,
in the first stage Na2S containing water of crystallisation having an Na2S content of 60 to 62 wt.% is used.
3. Process according to claims 1 and 2
characterised in that ,
a vacuum of between 0.6-10 and 70-10 Pa is used.
4. Process according to claims 1 or 3, characterised in that, in order to produce a polysulphide of the general formula (III), one equivalent of the hydrated monosulphide is reacted with n(x-l) equivalents of sulphur, wherein n assumes a value of 1 5. Process according to claims 1 to 4, characterised in that the temperature during the reaction to yield the polysulphides is increased as a function of the phase transition temperature of the

-16-
sulphide hydrates in such a manner that it is always below the particular relevant transition temperature.
Dated this 9th day of December 1997.
This invention relates to a process for the production of
bis(silylorganyl)polysulphanes of the general formula
(R1R2R3SiR4)2Sx (I)
in which
R1 , R2 , R3 : mean identically or differently from each
other, branched and unbranched alkyl and/or is [sic] aryl residues, in particular phenyl, toluyl, benzyl;
R4 : means a divalent alkylidene residue having a
chain length of 1-8 C atoms, or
-(CH2)n-C6H4-(CH2)n- (n= 1 to 4);
by reacting haloalkylalkoxysilanes or
haloalkoxysilanes of the general formula
R1R2R3SiR4x (II)
with a polysulphide of the general formula
M2SX (III),
which process is characterised in that in a first stage dehydrated polysulphides are obtained by reacting a sulphide hydrate containing water of crystallisation with sulphur under a vacuum at a temperature of 60 to 300°C.

Documents:

02332-cal-1997 abstract.pdf

02332-cal-1997 claims.pdf

02332-cal-1997 correspondence.pdf

02332-cal-1997 description(complete).pdf

02332-cal-1997 form-1.pdf

02332-cal-1997 form-2.pdf

02332-cal-1997 form-3.pdf

02332-cal-1997 form-5.pdf

02332-cal-1997 form-6.pdf

02332-cal-1997 gpa.pdf

02332-cal-1997 priority document other.pdf

02332-cal-1997 priority document.pdf

2332-cal-1997-granted-abstract.pdf

2332-cal-1997-granted-claims.pdf

2332-cal-1997-granted-correspondence.pdf

2332-cal-1997-granted-description (complete).pdf

2332-cal-1997-granted-form 1.pdf

2332-cal-1997-granted-form 2.pdf

2332-cal-1997-granted-form 3.pdf

2332-cal-1997-granted-form 5.pdf

2332-cal-1997-granted-form 6.pdf

2332-cal-1997-granted-gpa.pdf

2332-cal-1997-granted-letter patent.pdf

2332-cal-1997-granted-priority document.pdf

2332-cal-1997-granted-reply to examination report.pdf

2332-cal-1997-granted-specification.pdf

2332-cal-1997-granted-translated copy of priority document.pdf

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Patent Number

194893

Indian Patent Application Number

2332/CAL/1997

PG Journal Number

30/2009

Publication Date

24-Jul-2009

Grant Date

02-Sep-2005

Date of Filing

09-Dec-1997

Name of Patentee

DEGUSSA AG

Applicant Address

BENNIGSENPLATZ 1,D-40474 DUSSELDORF

Inventors:

#	Inventor's Name	Inventor's Address
1	DR.JORG MUNZENBERG	FORSTHAUSSTRASSE 11,DE-63457 MANAU
2	DR.PETER PANSTER	IM LOCHSEIF 8,DE-63517 RODENBACH
3	MATTHIAS PRINZ	KURT-SCHUMACHER-STRASSE 10,DE-63579 FREIGERICHT

PCT International Classification Number

C07F 07/08

PCT International Application Number

N/A

PCT International Filing date

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	19651849.0	1996-12-13	Germany