DE1129937B - Process and arrangement for the recovery of the unconsumed starting materials in the production of hyperpure silicon by means of the reduction of silanes by hydrogen - Google Patents

Description

Process and arrangement for the recovery of the unconsumed raw materials in the production of hyperpure silicon by reducing silanes with hydrogen It is known to represent the purest silicon, as it is especially for semiconductor diodes, Transistors and the like. Is required, gaseous chlorosilanes by. Hydrogen too to reduce elemental silicon, with as a reaction product except newly formed Chlorosilanes mainly produce hydrogen chloride. Suitable chlorosilanes for this purpose are in particular Silicochloroform, SiHC13, and Tetrachlorosilicon, Si C14. The reaction can be brought about, for example, that in one Mixture of chlorosilane and hydrogen an electrical discharge is operated or that the temperature of the gas mixture is increased to about 800 ° C. or more. In this process, a large part of the chlorosilanes, generally about 7011 / o, not consumed. It is known to cause the unused chlorosilane residues Freeze out at -120 ° C and recover the hydrogen chloride by freezing out to be deposited with liquid air at -186 ° C. Because the liquefaction point of hydrogen chloride is already at -85 ° C, at least a part falls in this known process of the hydrogen chloride already together with the silanes; to recover the The deposition product obtained at -120 ° C must therefore still be pure chlorosilanes be distilled. In addition, the hydrogen chloride becomes solid at -186 ° C deposited, which can lead to clogging of the separation system.

The invention relates to a method for recovering the unused raw materials in the production of hyperpure silicon by means of reduction of silanes by hydrogen. It consists in that from the reduction vessel outflowing mixture of hydrogen chlorosilanes and hydrogen chloride in a first Cold trap is cooled to a temperature a little above -85 ° C, at which most of the chlorosilanes involved are deposited in liquid form, and that the remaining mixture by at least one more, with an adsorber large surface is fed, cooled in the same way cold trap, in which the remaining chlorosilanes are collected. For cooling the cold traps Solid carbon dioxide (sublimation point -78 ° C) is particularly suitable. In which Process according to the invention, the chlorosilanes without contamination by hydrogen chloride, which is not appreciably soluble in the silanes. That will be advantageous Mixture precooled after flowing into the first cold trap according to the countercurrent principle. The first cold trap preferably consists of a coil and one attached to it subsequent part of large cross-section, in which the essentially already in the chlorosilane mist formed by the coil can sink. It is beneficial to be in to install parts of the coil which cause turbulence in the gas flow; The initially very small mist droplets are deposited in the gas eddies created in this way together to form larger drops, which due to their higher sinking speed Facilitate settling of the mist in the subsequent part of large cross-section.

The method according to the invention makes it possible after the deposition of the chlorosilanes to wash out the hydrogen chloride with water, so that all starting materials or reaction products (with the exception of hydrogen, which remains gaseous) in liquid form can be recovered and therefore in a simple manner from the separation plant can be removed. In this context it should be noted that in itself when washing out the hydrogen chloride with water, solid silicon compounds in finer distribution can arise if chlorosilanes are still used in this process step are contained in the gas mixture. In the process according to the invention however, the chlorosilanes are excreted so completely beforehand that disturbances by separating solid parts in the pipes and valves of the separation system do not occur. If the purest water is used to wash out the hydrogen chloride, the purest hydrochloric acid obtained in this way is a valuable "by-product" of the procedure.

An embodiment of the method according to the invention is given the drawing explained.

In the drawing, 1 denotes a first cold trap. The mixture from hydrogen, chlorosilanes and hydrogen chloride occurs in the direction of the arrow 2 first of all into a coil 3, in which there is already cooled gas is pre-cooled. Another pipe is connected to the coil 3 Coiled pipe 4, which is directly from the coolant 6 (mixture of solid carbonic acid and methyl alcohol). In the coil 4 are angled sheet metal strips 4 a used, which cause a turbulence of the flowing gas, whereby the drops of chlorosilane mist already formed in the line 4 become larger Droplets agglomerate. The mixture then flows into a container 5 with a large cross-section, in which the flow rate is so low that the chlorosilane mist is can settle. The rate of descent of the mist droplets formed in the pipe 4 is about 5 mm / sec; the cross section of the container 5 and the one flowing through it per unit of time The amount of gas must therefore be measured in such a way that the flow velocity in the left Part of the container in which the gas mixture rises is below this value. It succeeds in this way when carrying out the process on an industrial scale Depending on the flow rate, about 90 to 97% of the chlorosilanes are in liquid form to be deposited. The liquefied chlorosilanes are denoted by 7 in the drawing.

The remaining gas mixture now flows through a pipe 8 that surrounds the cooling coil 3 and through a valve 9 to two further cold traps 10 and 11, which are also cooled with a mixture of methyl alcohol and solid carbonic acid (12) and charged with silica drying gel 13 are. In the cold traps 10 and 11, the remaining 10% of the chlorosilanes are practically completely adsorbed.

The mixture of hydrogen and hydrogen chloride then passes through one or more wash basins 25 in which the hydrogen chloride is washed out with water. Ultrapure water is used for washing; the purest hydrochloric acid produced can be drained off from time to time at 22. At 23 water can be refilled.

The remaining hydrogen is then pre-dried in a vessel 26 filled with glass beads and compressed by a compressor 27 . Most of the water vapor is separated off in a condenser 28 cooled with ice water. For the combustion of oxygen residues, the hydrogen is then passed over a platinum or palladium contact 29 ; a final drying is carried out in a cold trap 30 charged with liquid air or solid carbon dioxide. Instead, it can also be dried with phosphorus pentoxide.

To draw off the liquid chlorosilanes separated in the vessel 5, a siphon 35 is provided, which leads into a vessel 36. The vessel 36 is provided with a closable outlet 37, the inlet opening 37 a of which is slightly higher than the outlet opening 35 a of the lifter 35. This ensures that the liquid column in the lifter 35 can never be interrupted. To fill the lifter 35, the valve 9 is temporarily closed; this creates an overpressure in the vessel 5, which presses the liquid 7 into the siphon 35. Even when the valve 9 is open, the pressure in the vessel 5 is always slightly higher than in the vessel 36.

The cold traps 10 and 11 are from time to time at room temperature flushed with hydrogen, which was adsorbed by the silica dry gel Absorbs chlorosilanes. You can use this chlorosilane-laden hydrogen again Introduce into the separation system at 2 in order to remove another 9% of the chlorosilanes to win back. During the regeneration of the cold traps 10 and 11 can through Switch over the valves 14 and 15 to two further silica dry gel cold traps 16 and 17 are switched on, so that uninterrupted operation of the system is possible is.

In order, on the one hand, to enable pressure equalization in the vessel 36, on the other hand however, a shut-off device 40 is used to prevent the ingress of air humidity provided, the shut-off liquid 41, for example, mercury or a oil with low vapor pressure (paraffin oil, pump oil). Before the shut-off device 40 is a safety vessel 42 that prevents the shut-off liquid 41 in the vessel 36 prevented.

Claims (7)

PATENT CLAIMS: 1. Method for recovering the unused Starting materials for the production of hyperpure silicon by reducing chlorosilanes by hydrogen, characterized in that the flowing out of the reduction vessel Mixture of hydrogen, chlorosuane and hydrogen chloride in a first cold trap is cooled to a temperature a little above -85'C, at which the involved Chlorosilanes are deposited in liquid form for the most part, and that that rest of the mixture by at least one more, with a large adsorber Surface charged, cooled in the same way cold trap is performed in the the remaining chlorosilanes are collected. 2. The method according to claim 1, characterized characterized in that the cold traps are cooled by solid carbon dioxide. 3. Procedure according to claim 1, characterized in that the mixture when flowing into the first cold trap is pre-cooled according to the countercurrent principle. 4. The method according to claim 1, characterized in that after the separation of the chlorosilanes, the hydrogen chloride is washed out with water. 5. The method according to claim 4, characterized in that that the purest water is used to wash out the hydrogen chloride. 6. Arrangement for carrying out the method according to claim 1, characterized in that the first cold trap from a pipe coil and one subsequent to this Part of a large cross-section. 7. Arrangement according to claim 6, characterized in that parts are built into the pipe coil which cause turbulence in the gas flow. Considered publications: U llmann, Enzyklopadie der technischen Chemie, Vol. I, 3rd edition, pp. 333, 341; Journal of Inorganic and General Chemistry, Volume 190. Pp. 257, 258.