SE461037B - COATED BY COAL AND SILICON Dioxide CONTINUOUSLY MAKING LIQUID SILICONE IN A REACTOR - Google Patents

Description

461 10 15 20 057 The method according to the invention thus offers a process in which the above-mentioned losses of SiO are reduced or eliminated, and the content of residual SiC in the product is minimized.

The method according to the invention can be illustrated in the following way.

In the first step, a carbothermal reduction of SiO2 is carried out in a first zone containing an excess of carbon to form SiC according to S102 + 2C> 2 SiO 2 + 2 CO (1) 2 SiO 2 + 4C - 9 SiCS + 2CO (2 ) or a total of 2 SiO 2 + 6C ~ ---> 2 SiCs + 4CO (3).

In the second step, the SiC produced in the first step is used to further reduce SiO2 according to SiO2 + SiCs - δ Sil + S109 + CO (4), and SiO + SiC - δ 2 Si + CO (5 ), or gsl total SiO2 + 2SiCS> 3 Sil + 2CO (6).

The total reaction for the two combined steps (equation (3) plus equation (6) is 3SiO + 6C> 3Si + GCO (7). 2 l,. .-. Fl nwwwuu 10 15 20 25 30 3 461 057 The invention according to the invention the method is advantageously carried out in a shaft furnace which is kept filled with piece-shaped carbon material.

This reactor suitably has at the top a feed means for piece-shaped carbon material, as well as a line for drawing gases produced and introduced into the system. At an upper level of the reactor there are devices for feeding silica and heat energy into a first reaction zone.

At a second lower level in the reactor, there are means for feeding in silica and heat energy for carrying out the second reaction step. The lower part of the reactor is designed in a conventional manner to allow draining of formed silicon, and can advantageously be designed to allow temporary collection of liquid silicon for batchwise draining thereof from the reactor.

The means for supplying heat energy are devices for supplying combustion-independent energy, namely plasma generators in which particulate SiO 2 is injected thereon.

The process according to the invention according to the above-mentioned stoichiometric equations will now be described in more detail in connection with the appended single drawing figure, which schematically shows an apparatus for carrying out the method according to the invention.

The apparatus shown schematically in the drawing comprises a shaft furnace 1 which is provided with at least one plasma generator 2 on an upper level, and at least one plasma generator 3 on a lower level. The furnace also has at the upper part 9 a conventional lock 4 for feeding piece-shaped carbon, as well as a line 7 for drawing gases which are produced and introduced into the furnace. Furthermore, injection devices 5 and 6, respectively, are shown for injecting particulate SiO2 at each plasma generator. Furthermore, drainage devices 8 are shown at the bottom of the furnace for periodic removal of the product, liquid silicon.

The upper part of the shaft furnace 1 is used for carrying out the first step of the process and comprises the plasma generators 2 at the upper level and the furnace volume above this upper level. This furnace volume is filled with lumpy carbon fed through the upper part 9. Plasma gas which may be recycled from other gas or other suitable gas, as well as particulate SiO2 which is injected into the plasma gas, enters the carbon bed and reacts according to reactions (1) and (2) to form of SiC and CO. The temperature in this reaction zone after substantially complete reaction will be at least 190 DEG C. and preferably higher, and this temperature will decrease to about 300 DEG C. at the top of the shaft furnace as the piece of charcoal fed there moves downwards and is heated by the rising the gases to the reaction temperature.

It is quite clear that a significant part of this carbon preheating will be effected in the upper part of the reactor volume so that most of the volume above the upper plasma generator level 2 will be at or near the reaction zone temperature. These conditions will favor complete reduction of all SiO 2 according to reaction (2). The SiC produced in this first step will move downwards together with any unreacted coal down into the lower part of the shaft furnace 1, which part comprises the plasma generators at the lower level 3 and the devices for collecting and subtracting Sil, and this lower part used for the second step of the implementation process. In this second step, additional SiO2 is fed to the lower level together with plasma gas from the plasma generators at this level and will react with downflowing SiC and unreacted carbon to form Sil and CO according to reactions (4), (5) and optionally Siog + C> Sil + Co (8). . al .. .www-www 10 15 20 25 30 5 461 037 Produced Sil will accumulate in the kiln volume at its bottom and be periodically removed by tapping in a conventional manner. According to a preferred form of the invention, the furnace is started by filling its lower part with piece-shaped SiC and filling its upper part with piece-shaped carbon which could be graphite or coke. Thereafter, the plasma generators at levels 2 and 3 can be operated with suitable inert plasma gas to heat the system to the reaction temperature. A continuous production of Sil can then be started by injecting SiO2 at the plasma generators 2 and 3, to carry out the previously stated equations. An example of operation of the process according to the invention using relative trainer accumulators is given in the following table, for a production flow of one tonne of silicon per hour.

In the example, reaction zone temperatures of about 190 ° C were maintained.

Example of operation at a production of 1 ton Si per hour, per ton Si Carbon consumption, kg 855 Silica, kg 2139 to first stage 1426 to second stage 713 Electricity, kWh 7924 to first stage 4546 to second stage 3378 Plasma gas, kmol 49 to first step 34 to the second step 15 Outgoing gas, kmol * 125 CO, mole fraction 0.938 N2, mole fraction 0.062 Frangas Temperature OC aa 1250 461 037 6 * The plasma gas in this operating example is recycled outgoing gas.

Claims (6)

10 15 20 25 7 461 037 P a t e n t k r a v A method of continuously producing liquid silicon from carbon and silica in a reactor, wherein in a first step a first proportion of the silica is reacted with carbon during the supply of heat energy to form silicon carbide and in a second subsequent step a second The proportion of silica is reacted with the silicon carbide produced in the first stage with the supply of heat energy to form liquid silicon, characterized in that the first stage is carried out by introducing plasma gas and SiO in the reactor to form a first reaction zone located at a level above a second reaction zone arranged in the reactor containing primary silicon carbide formed in the first zone, the second step being carried out in the second zone during introduction of plasma gas with silicon dioxide injected therein. . 2. A method according to claim 1, characterized in that the first proportion of silica is selected to be approximately 2/3 and that the second proportion of silica is thus selected to be approximately 1/3. 3. A method according to claim 1 or 2, characterized in that the temperature in the first stage is maintained at at least 1900 ° C. A method according to any one of claims 1 to 3, wherein the temperature in the second stage is maintained at at least 19 ° C. 5. A method according to any one of claims 1 - 4, wherein the reactor vessel is charged with carbon in its upper part. k ä n n e t e c k - k ä n n e t e c k - 461 037 6. A method according to any one of claims 1 - 5, characterized in that the reactor is initially filled with particulate carbon in its upper part and with SiC in its lower part at the top of the first zone, and that inert plasma gas is injected into the two initially filled the reaction zones until the operating temperature condition is reached in the reactor, after which SiO2 and plasma gas are injected into the zones for continuous production of liquid silicon.