DE3425424C3 - Process for the preparation of alkylhalosilanes - Google Patents

Description

The present invention relates to a method for Preparation of alkylhalosilanes in which an alkyl halide and powdered silicon in the presence of an effective amount of a Catalyst containing copper according to claims 1 to 6.

Prior to the present invention were methylchlorosilanes by a reaction between powdered silicon and methyl chloride produced in the presence of a copper catalyst, as in US-PS 23 80 995 shown. Improved results were achieved Using a fluidized bed reactor, as in the US-PS 23 89 931 shown. Further improvements in the Production of special methylchlorosilanes was achieved when Zinc used in combination with copper catalyst as a promoter was as shown in US-PS 24 64 033. This document teaches that a proportion of about 2 to about 50% by weight of copper in parenteral form or as halide or Oxide, and preferably 5 to 20% and about 0.03 to about 0.75 wt .-% Zinc in the form of zinc halide, zinc oxide or zinc metal or mixtures thereof, wherein the weight of copper and zinc are based on the weight of silicon, as a promoter for the preparation of dialkyl-substituted dihalosilanes, such as dimethyldichlorosilane, in direct reaction between silicon powder and methyl chloride can be used.

According to the study of Gilliam according to US-PS 24 64 033 found Radosavlyevich et al., That microns of silver, in contact added with compounds resulting from the reaction of powdered Silicon and methyl chloride in the presence of copper (I) chloride yield, lowered the yield of methylchlorosilanes, while tin and calcium chloride increase the rate of formation of methylchlorosilanes as shown in "Influence of Some Admixtures on the Activity of Contact Masses for Direct Synthesis of Methylchlorosilanes, "Institute of Inorganic Chemistry, Belgrade, Yugoslvia (1965).

The term "methylchlorosilanes" used hereinafter includes Dimethyldichlorosilane, which is the preferred methylchlorosilane and a variety of other silanes, such as tetramethylsilane, Trimethylchlorosilane, methyltrichlorosilane, silicon tetrachloride, Trichlorosilane, methyldichlorosilane and dimethylchlorosilane.

In addition to the above methylchlorosilanes is formed during the production of the crude methylchlorosilane "residue". Residue means Products in the crude methylchlorosilane with a boiling point <70 ° C at atmospheric pressure. Backlog consists of such Materials such as disilanes, z. Symmetric 1,1,2,2-tetrachlorodimethyldisilane, 1,1,2-trichlorotrimethyldisilane, disiloxanes, Disilmethylenes and other higher-boiling species, z. Trisilanes, trisiloxanes and trisilmethylenes. Next the tailor is also interested in the T / D weight ratio of the crude methylchlorosilane. The T / D ratio is the ratio of methyltrichlorosilane to dimethyldichlorosilane in Methylchlorsilan reaction raw product. Thus there is an increase of the T / D ratio indicates that the production of the preferred Dimethyldichlorosilane has dropped.

Although, as taught by the prior art, zinc or tin valuable promoters for copper catalysts or copper-silicon contact material in the reaction between powdered silicon and methyl chloride, it has been found that the Forming rate of crude methylchlorosilane and the T / D ratio often unsatisfactory.

If a rate constant is defined for the formation of crude methylchlorosilane, the term "K _p " or "reaction rate constant for methylchlorosilane product" will often be used by those skilled in the art. A more detailed derivation of K _p can be found below immediately before the examples.

K _p values can be obtained with a device shown in FIG . When a mixture of copper and powdered silicon containing 5% by weight of copper is used to prepare methylchlorosilane, a "K _p " (g of silane / g of silicon, h) having a numerical value on a relative scale of about 13 to be obtained. A K _p of 16 can be obtained from a mixture of powdered silicon with 5 wt% copper and 0.5 wt% zinc. A K _p of 45 can be obtained by reacting a mixture of powdered silicon with 5% by weight of copper and 0.005% by weight of tin with methyl chloride.

Although the above K _p values indicate that tin-promoted copper catalyst can provide superior methylchlorosilane formation rate when used with powdered silicon and methyl chloride, it has been found that the tin-activated copper catalyst selectivity may be inferior to a zinc-activated copper catalyst.

As defined herein below, the term "selectivity" means the ability of a catalyst to maximize the formation of dimethylchlorosilane, such as e.g. As shown by a reduction in the value of the T / D ratio and a decrease in the percentage of residue. One finds z. For example, although a higher K _p can be obtained when tin is used with copper to catalyze the reaction between powdered silicon and methyl chloride, there is also a significant increase in the T / D ratio as compared to using a zinc activated one copper catalyst.

The present invention is based on the surprising finding that direct reactions between powdered silicon and methyl chloride in the presence of an effective amount of a copper-zinc-tin catalyst, as defined hereinafter, K _p values greater than about twice the value for zinnaktivierten copper catalyst such as as discussed above, while at the same time significantly improving selectivity over zinc-activated copper catalyst and over tin-promoted copper catalyst. Specifically, optimum selectivity and maximum K _p values can be obtained by using the direct method with a mixture of powdered silicon, copper, tin and zinc, 0.5 to 10% by weight of copper, except in the combination of partially oxidized copper contains up to 0.2% by weight of lead and about 0.42% by weight of tin, while its water content may vary from 0 to 0.75% by weight, with copper formate, based on the weight of silicon, containing wherein the copper may be present in the free state or in the form of a copper compound, as defined below, with from 0.01 to 0.5 parts zinc per part copper and from 200 to 3000 ppm tin, relative to copper, both zinc and Also, tin is also expressed in weight of metal, although optionally used as a zinc compound or a tin compound, as defined below.

An advantageous embodiment of the invention is a method for the production of methylchlorosilanes, which reduces the rate of formation of Dimethyldichlorosilane considerably increased, while at the same time the weight ratio of methyltrichlorosilane to dimethyldichlorosilane decreased and the weight percentage of products in the resulting crude methylchlorosilane with a boiling point kept above 70 ° C at atmospheric pressure or lowered is characterized in that methyl chloride and powdered Silicon in a reactor in the presence of an effective Amount of copper-zinc-tin catalyst produced by Introducing a mixture of powdered silicon, copper or Copper compound, zinc or zinc compound and tin or tin compound, is reacted, wherein the copper or the copper compound, the tin or the tin compound and the zinc or the zinc compound together with powdered silicon and Methyl chloride are introduced and the introduction of copper, Tin and zinc or their compounds at a speed sufficient, in the reactor, a copper-zinc-tin catalyst with an average composition of From 0.5 to 10% by weight of copper relative to silicon, except in the combination of partially oxidized copper containing up to 0.2% by weight of lead and about 0.42% by weight of tin, while its water content is from 0 to 0.75 wt.%, With copper formate, 200 to 3000 ppm Tin relative to copper and 0.01 to 0.5 parts and preferably Maintain 0.01 to 0.30 parts of zinc per part of copper. It is particularly preferred, the inventive To carry out the process continuously in a fluidized bed reactor, silicon material with catalyst contents from the reactor is removed and returned.

While methyl chloride is preferably used in the practice of the invention, other C _(1-4) alkyl chlorides, e.g. As ethyl chloride, propyl chloride can be used.

Methyl chloride or an inert gas, such as argon, or a mixture thereof, can be used to make the bed of silicon particles to fluidize in the reactor with or without catalyst contents. The silicon present in the fluidized bed can be a Have particle size below 70 microns, with an average size over 20 μm and under 300 μm. The mean diameter of the Silicon particles are preferably in the range of 100 to 150 μm.

Silicon is usually in a purity of at least 98 wt .-% silicon and then becomes silicon particles crushed in the area described above and as needed fed to a suitable reactor. Although a fluidized bed is preferred, the inventive method in other reactor types, such as a fixed bed and a stirred bed, be applied. Preferred is a fluidized bed reactor used as optimal selectivity and maximum amount Methylchlorosilane is obtained. The inventive method is at a temperature in the range of 250 to 350 ° C and more preferably at a temperature in the range of 260 to 330 ° C performed. The reaction can be under continuous Conditions or as a batch reaction.

The term "continuous reaction" or "continuous Conditions "with regard to the description of the reaction of powdered silicon and methyl chloride in the presence of the copper-zinc-tin catalyst means that the reaction in a fluidized bed reactor under continuous conditions or in a fluidized bed reactor or a stirred bed reactor performed under simulated continuous conditions becomes.

A fluidized bed reactor, shown in Figure 1, shows the reaction under continuous conditions. Fig. 2 shows the process according to the invention using a fluidized bed reactor with a stirrer which can be operated batchwise. The stirrer is used to agitate and aggravate fluidized silicon and catalyst components such as cuprous chloride, zinc metal dust, and tin powder to initiate the direct reaction between powdered silicon and methyl chloride.

If desired, before contact with methyl chloride Contact mass of powdered silicon with copper-zinc-tin catalyst be prepared to the formation of methylchlorosilanes to facilitate. Preferably, a reactive Copper compound, such as copper (I) chloride, with suitable Quantities of powdered silicon, tin and zinc, mixed and heated to a temperature of about 280 to 400 ° C.  

It is also advisable, the inventive method under to carry out a pressure of 1 to 10 bar in cases where a fluidized bed reactor is used because higher Pressure the rate of conversion of methyl chloride into Increases methylchlorosilanes.

Methyl chloride gas can be passed continuously through the reactor be used to fluidize the reaction mass, and off gaseous methylchlorosilanes and the be discharged unreacted methyl chloride. The gaseous Crude product mixture and entrained reaction particles be from the fluidized reactor and by one or several cyclones passed to the larger material particles separate from the product gas stream. These particles can be used for Recycled reactor for further use in the process, to the yield of dimethyldichlorosilane from the silicon to keep maximum. Smaller particles become with the product stream discharged and the stream is then condensed.

Purified methyl chloride is heated and for further formation of methylchlorosilanes through the fluidized reactor recycled. The stream of crude methylchlorosilane becomes one Distillation plant led to generated by the process various chlorosilane fractions in substantially to distill out pure form. It is necessary to use dimethyldichlorosilane and to distil the other chlorosilanes and to be cleaned so that they can be used in the process of manufacture of silicone materials can be used.

To the copper compounds used to make the copper-zinc-tin catalyst or particulate silicon-copper Zinc-tin contact material used Carboxylic acid salts of copper, such as Copper formate, copper acetate, copper oxalate. copper formate is the preferred carboxylic acid salt of copper that continues characterized as practically anhydrous granular material of technical copper (II) formate dihydrate (Cu) (CHO₂) ₂ · 2H₂O) or copper (II) formate tetrahydrate (Cu (CHO₂) ₂ · 4H₂O) and a BET surface area of 0.5 to 20 m² / g having the nitrogen adsorption method.

In addition to carboxylic acid salts of copper, such as copper formate, can as a source of copper in the practice of the invention partially oxidized to produce the copper-zinc-tin catalyst Copper can be used. In cases where partially oxidized or cemented copper has a content of tin relative to copper, which is the for the production of the copper-zinc-tin catalyst exceeds required range can be satisfying Results are achieved when the reactor of Excess tin by using partially oxidized copper virtually free of tin for a predetermined period of time is rinsed free. Further, mixtures of tin-containing and partially oxidized copper used virtually free of tin be to the desired tin concentration relative to copper in the practice of the invention Maintain procedure.

An example of the preferred partially oxidized copper, referred to as Copper source for the production of the copper-zinc-tin catalyst can be used, about characterized as follows:

CuO | 32-33% Cu₂O 57-59% Cu⁰ 5-10% Fe 350 ppm sn 54 ppm pb 22 ppm insoluble ~0,05% Bi, Ti <20 ppm

Other copper materials, the used for the preparation of the catalyst are particulate copper (II) chloride, copper (I) chloride, particulate copper metal, etc.

Zinc metal, zinc halides, e.g. As zinc chloride and zinc oxide have proven to be effective catalyst components. Tin metal dust (<44 μm), tin halides, such as tin tetrachloride, tin oxide, tetramethyltin and Alkyltin halides can also be used as a source of tin for the production of the copper-zinc-tin catalyst.

The copper-zinc-tin catalyst or powdered silicon Copper-zinc-tin contact mass can be produced be by introducing the above ingredients into the reactor, separately or as a mixture, premix, Alloy or mixture of two or more of the different Constituents in elemental form or as compounds or their mixtures.

The methyl chloride fed to the fluidized bed reactor or is subjected to the direct process, is heated to a temperature heated above its boiling point and as gas fast enough passed through the reactor to the bed of silicon particles, activated by copper-zinc-tin catalyst, too fluidize.

The process according to the invention can be carried out in a fluidized bed reactor be carried out with a jet mill on the ground. A suitable jet mill arrangement is disclosed in US-PS 31 33 109 shown where large silicon particles are crushed. The resulting finer silicon particles and catalyst can further in the reactor to produce the desired alkylhalosilanes be used.

Another method for improving silicon recovery involves the grinding of the surface of silicon particles. The treatment of small and large silicon particles is in the US-PS 42 81 149 reproduced, their disclosure content by this reference in the present Registration is included. After that, the smaller silicon particles advantageous from the fluidized bed reactor removed, rubbed off and then the particles returned.

A further improvement is disclosed in US-PS 43 07 242, after which silicon fines and copper catalyst the reaction mixture are selectively separated with cyclones, the particles classified by size and the particle material recycled to the reactor for further use.

In order to better enable the person skilled in the art, some of the preferred embodiments of the prakti  implementation to understand the invention, reference is made to the figures, the schematic representations of fluidized bed reactors are.

Fig. 1 is a schematic representation of a fluidized bed reactor operating under continuous conditions and for fluidizing a bed of powdered silicon means for introducing methyl chloride under pressure to fluidize such a bed, a heat exchanger element for controlling the temperature of the bed, means for introducing a Copper source, separate means for introducing a tin and a zinc source, means for recycling silicon fines and catalyst, and means for separating crude methylchlorosilane.

Figure 2 is a schematic representation of a fluidized bed reactor which can be operated batchwise and has a fluidized bed stirrer which serves to facilitate the formation of a powdered silicon-copper-zinc-tin contact mass from a powdered silicon, copper compound feedstock feedstock Copper (I) chloride, powdered zinc metal and powdered tin metal, to facilitate or facilitate.

More specifically, in Fig. 1, a fluidized bed reactor is shown at 10 , the upper end of a fluidized silicon bed at 11 supported by methyl chloride introduced into the reactor at ports 12, 13 and 14 . Metallic copper or copper compound in the form of copper oxide, copper formate or a copper halide such as cuprous chloride can be continuously introduced into the fluidized bed through the supply line 15 . Zinc metal or its compounds, together with tin metal or a compound thereof, such as tin oxide, may be introduced at 16 together with supplementary silicon. In cases where tin in the form of a tin halide such as tin tetrachloride, is introduced, it can be introduced at 14 at 17, or together with methyl chloride.

The temperature of the fluidized bed is maintained between 260 and 300 ° C by use of a heat exchanger through which heat transfer fluid flows at 18 and 19 . A cyclone 20 continuously returns particulate silicon to the reactor. Silicon fines, which are not captured by the cyclone 20 , are conducted via a line 21 to a second cyclone 22 . Fines obtained from this are stored at 24 and 25 and returned to the reactor at 26 continuously. In cases where fines are not captured at the cyclone 22 , they can be conveniently removed at 23 . Along with silicon fines, catalytic amounts of copper, tin and zinc are also returned to the reactor via line 26 to help keep the catalyst in the critical range.

Referring more particularly to Fig. 2, there is shown a fluidized bed reactor 30 having a fluidized bed 31 , a carrying perforated plate 32 through which fluidizing methyl chloride can flow, a thermocouple sensor 33 for monitoring the temperature of the fluidized bed, an orifice 34 for introducing a mixture of powdered materials Silicon and catalyst, an opening 36 for separating crude methylchlorosilane, an opening 37 for introducing methyl chloride, a thermocouple sensor at the bottom of the passageway for monitoring the temperature of the methyl chloride, a jacketed cylinder 40 having heaters 41 and 42 , respective power sources 43 and 44 and an outer jacket 50 serving as an insulator for the heaters 41 and 42 .

As previously discussed, the reaction rate constant K _p gives the rate of crude methylchlorosilane. K _p can be achieved by transforming and integrating the equation

F × dX = 2 × R × dm _Si (1)

where F is the methyl chloride stream (mol / h), X is the proportion of converted methyl chloride and R is the rate the formation of methylchlorosilane in units of

is and m _{Si is} the mole silicon in the reactor. Equation (1) is based on the assumption that all crude methylchlorosilane is dimethylchlorosilane. The equation obtained by converting and integrating the above expression is

A simplified kinetic model

empirically derived, is found in "Organohalosilanes: Precursors to Silicones ", R. Voorhoeve, p. 229, Elsevier (1967), in which

K _p = molar reaction rate constant for silane

K = adsorption equilibrium constant for MeCl (A), and silane (B), (bar ^-1 ). In this work, values for K _A and K _B were assumed to be 6.8 × 10 ^-3 bar ^-1 and 0.4 bar ^-1 , respectively.
P _A = pressure, MeCl (bar).
P _B = partial pressure, silane (bar).

Equation (3) is substituted into equation (2), which is then numerically integrated to give the mass reaction rate constant K _p in the unit

to obtain.

In order to enable the person skilled in the situation, the invention better Being able to perform practically are the following examples by way of illustration, not by way of limitation given. All parts are parts by weight.

example 1

A fluidized bed reactor similar to that shown in Figure 2 is assembled consisting of three concentric 0.5 m glass tubes with internal diameters of 70, 51 and 38 mm. The 38 mm reactor tube had a mid-tube distributor plate and a stirrer with a vane over the distributor plate. The 38 mm reactor tube is placed in the 51 mm stovepipe with a tin oxide resistive coating and the 51 mm stovepipe is enclosed in the 70 mm insulated tube.

A mixture consisting of 100 parts of powdered silicon, 7.8 parts of copper (I) chloride powder, 0.5 parts of zinc dust and 0.005 parts of powdered tin is prepared. The powdered Silicon has an average surface area of 0.5 m² / g, a maximum particle size of up to about 70 microns and Impurities as follows:

composition Quantity (ppm) iron 5600 aluminum 2700 titanium 850 manganese 200 calcium 160 nickel 120

The copper (I) chloride used in the above mixture is a practically pure granular material of <44 μm Particle size less than 200 ppm iron and each contains less than 20 ppm of the following elements: Ni, Bi, Mg, Sn, Pb and Zn. The tin oxide used in the above mixture and zinc metal are less than about 100 ppm metallic and non-metallic impurities. The mixture of Silicon powder and catalyst components are used in the reactor described above at a temperature of about Introduced 300 ° C, with methyl chloride up through the distributor plate flows and the stirrer is set in motion to move the fluidized bed. After about 5 minutes stirring of the fluidized bed form about 3.0 parts of silicon tetrachloride and used lower amounts of perchlorinated polysilanes per part Copper (I) chloride, as the volatiles show, resulting from the reaction between copper (I) chloride and give the silicon powder, which intercepted in a cooler and analyzed by gas chromatography.

The direct reaction between the powdered silicon and methyl chloride in the presence of the resulting powdered silicon-copper-zinc-tin contact mass may continue until about 40% of the silicon is reacted at 300 ° C. In the course of the reaction, crude methylchlorosilane is continuously condensed and periodically sampled and weighed. The K _p value is calculated and T / D ratio and percentage residue are determined by gas chromatography. In one series of reactions, the influence of tin on velocity (g silane / g silicon / h) and the selectivity at 300 ° C with mixtures with a ratio of zinc / copper at 0.10 is determined, while the ratio of TpM tin / copper over a range of 0 to 3000 is varied. The following approximate results are obtained, where the percentage of copper, as defined above, is based on the weight of the silicon:

Table I

Influence of tin on speed and selectivity

Batches at 300 ° C, Zn / Cu = 0.10

Various approaches under virtually similar conditions over a Sn / Cu TpM range of 0 to 5000 provide a K _p of 16 to 331, a percent range residue of 1.6 to 6.4, and a T / D ratio range of 0.060 to 0.073 , At 1.5% Cu, over a 1000 to 3000 Sn / Cu TpM range, a K _p range of 29 to 75, a percent range residue of 2.3 to 5.2, and a T / D ratio range of 0.039 to 0.037 received.

Another approach is to determine the selectivity and speed for a catalyst with a Ratio of zinc / copper over a range of 0 to 0.60, while maintaining a concentration of 1000 ppm Tin, relative to copper. The following approximate results will be receive:

Table II

The influence of the Zn / Cu ratio on the rate and selectivity (1000 ppm Sn / Cu)

A continuation of the same series takes place under practical same conditions using 1.5 wt .-% copper, based on silicon:  

Table IIA

Another series of reactions is carried out for determination the influence of copper concentration on velocity and selectivity at temperatures of about 300 ° C. The following Approximate results are obtained:

Table III

Except for the 0% Cu approach, the following table is IV a confirmation of Tables I-III and some of the above data. It shows the approximate influences of the present or the complete absence of different combinations of copper, zinc and tin on the speed and selectivity in terms of methylchlorosilane production as Result of the reaction of powdered silicon and methyl chloride.

Table IV

Influences of copper, tin and zinc on speed and selectivity

(Comparative Examples)

The above results show that the copper Zinc-tin catalyst a surprising speed improvement offers, while the selectivity regarding dimethyldichlorosilane production also improved considerably is compared to the use of a copper catalyst alone or one activated with zinc or tin alone Copper catalyst.

Example 2

A 25 ml stirred bed reactor was set up. He consisted of a stainless steel tube of about 46 cm in length with an inner diameter of 25 mm. He was with electric Double zone heaters equipped to a Reaction zone of about 25 × 152 mm to give. Further he was equipped with a stainless steel screw stirrer.

The stirred bed reactor was purged with nitrogen until the Stability preheated to 300 ° C. Then he became  with a mixture of powdered silicon as used in Example 1, 5% by weight of copper used in the form of partially oxidized copper, 0.5 wt .-% zinc, based on the copper weight, and 500 ppm tin per part copper, charged. The partially oxidized Copper had the following approximate composition:

CuO | 32-33% Cu₂O 57-59% Cu⁰ 5-10% Fe 350 ppm sn 54 ppm pb 22 ppm Insoluble ~0,05%

Specifically, in the stirred bed reactor, a mixture of 50 parts of powdered silicon, 2.9 parts of copper oxide, 0.25 Divide zinc metal and 0.0015 parts of tin metal introduced. The Mixture was mixed together and at a temperature of 300 ° C in the stirred bed reactor. An equimolar one Mixture of dimethyldichlorosilane and methyl chloride was then placed in the stirred bed reactor to charge pretreat. The dimethyldichlorosilane-methyl chloride stream was then stopped when the charge of sufficient dimethyldichlorosilane had been treated to a molar ratio of dimethyldichlorosilane to copper of at least 3 to form. Methyl chloride was then added to the reactor at a feed rate of 12.5 parts / h introduced. The reaction was finished after 16 h, and following speed and Selectivity results were obtained:

K _p 65-75 T / D 0.07-0.08 % Residue 4-5

The above results show that the invention used Copper-zinc-tin catalyst resulting from the use of partially oxidized copper as a copper source, used therefor can dimethyl dichlorosilane under simulated continuous To deliver conditions, taking a sufficient measure retained at selectivity.

Example 3

Silicon powder having an average particle size above about 20 microns and below about 300 microns is in a fluidized bed reactor fluidized with methylene chloride, which is continuously added a pressure of about 1 to about 10 bar is introduced. The reactor temperature is at about 250 to 350 ° C held. Partially oxidized copper of Example 2 is with continuously introduced at a speed that is sufficient about 0.5 to about 10 wt .-% copper, based on the Weight of fluidized silicon, maintain. tin tetrachloride gets into the fluidized bed reactor at least periodically introduced at a speed that is sufficient Tin concentration of about 200 to 3000 ppm tin, based on the weight of the copper, uphold. A mixture made of zinc metal dust and powdered silicon is laterally in introduced the fluidized bed reactor at a rate which is sufficient, a ratio of zinc to copper of about Maintain 0.01 to 0.25 parts of zinc per part of copper.

Together with the introduction of tin tetrachloride and zinc metal is applied silicon-containing material with copper Zinc-tin catalyst contents and in the form of an average Particle size of about 2 to 50 microns and a mixture of containing particulate silicon, copper, tin and zinc, at least periodically returned to the fluidized bed.

In the course of the continuous passage becomes a sample of the reaction bed and analyzed by atomic absorption. It is found that the bed is about 2% by weight copper on the weight of fluidized silicon, 0.08 parts of zinc and 0.001 part tin per part copper. The following Average results will be continuous over 96 h Received operation.

Table VI

The above values for K _p , T / D and% residue show that the copper-zinc-tin catalyst used in the present invention can provide a satisfactory dimethyldichlorosilane production rate while maintaining a high degree of selectivity under continuous reaction conditions in a fluid bed reactor.

Example 4

A mixture of 100 parts silicon powder, 7.8 parts copper (I) chloride, 0.005 part of tin powder and 0.5 part of zinc dust was mixed thoroughly. The mixture was then poured into a maintained above 300 ° C and purged with argon oven. The mixture was not stirred and left in the oven, until the reaction between the copper salt and silicon was complete. The end of the reaction was shown by cessation the formation of silicon tetrachloride. Based on This manufacturing process was a contact mass of powdered Silicon-copper-zinc-tin containing 5% by weight of copper metal, based on the silicon weight, 0.1 part of zinc per part of copper and 1000 ppm tin per part of copper.

The contact mass was transferred to a fluid bed reactor of 38 mm Inner diameter brought. The temperature was up 300 ° C and started with a stream of methyl chloride. On Cooler, seen in the flow direction behind the reactor, was used to recover chlorosilane crude products. The Forming rate of crude product was obtained by weighing the Crude product determined over predetermined time intervals. The composition of the crude product was determined by gas chromatography certainly. The following results were obtained after about 20% of the silicon had reacted, the also about the same results were after use from 80 to 90% of the silicon were obtained:

The above results show that the beneficial effects realized the copper-zinc-tin catalyst used in the invention can be when using powdered silicon as preformed contact mass for the production of dimethyldichlorosilane is present.

Claims (6)

A process for the preparation of alkylhalosilanes which comprises reacting an alkyl halide and powdered silicon in the presence of an effective amount of a catalyst containing copper, characterized in that it is reacted at temperatures in the range of 250 to 350 ° C and with a copper-zinc oxide. Tin catalyst containing 0.5 to 10 wt% copper, except in the combination of partially oxidized copper containing up to 0.2 wt% lead and about 0.42 wt% tin Water content of 0 to 0.75 wt .-%, with copper formate, based on silicon, and 200 to 3000 TpM tin and 0.01 to 0.5 parts of zinc per part of copper, carried out. 2. The method according to claim 1, characterized in that used as the alkyl halide methyl chloride. 3. The method according to claim 1, characterized in that it under continuous conditions in a fluidized bed reactor performs. 4. Process for the preparation of methylchlorosilanes, characterized in that Methyl chloride and powdered silicon in a reactor in the presence an effective amount of a copper-zinc-tin catalyst, wherein a mixture of powdered silicon, Copper or copper compound, zinc or zinc compound and tin or Tin compound, together with methyl chloride, at a rate sufficient in the reactor a copper-zinc-tin catalyst having an average composition from 0.5 to 10% by weight of copper, except in the combination of partially oxidised copper containing up to 0.2% by weight of lead and about 0.42% by weight of tin, while its water content is from 0 to 0.75% by weight, with copper formate, based on silicon, 200 to 3000 ppm of tin, based on copper, and 0.01 to 0.5 parts Zinc per part of copper to maintain introduces. 5. The method according to claim 4, characterized in that the average composition of the copper-zinc-tin catalyst by reacting the methyl chloride and the powdered silicon in a fluidized bed reactor under continuous conditions and continuous recycling of copper, zinc, tin or their Compounds as discharged material together with powdered silicon to the reactor. 6. The method according to claim 4, characterized in that partially oxidized copper as copper source for the copper-zinc-tin catalyst used, wherein the partially oxidized copper less than 2000 ppm tin, based on the weight of the copper.