EP2935100A1 - Method for processing finely divided solids during production of chlorosilanes - Google Patents

Abstract

The invention relates to a method for processing finely divided solids during the production of chlorosilanes, characterized in that the finely divided solids are hydraulically compacted to bodies of increased density. The invention also relates to the compacted article obtained by the method according to the invention, said compacted article being characterized by a bulk factor of the finely divided solids to be hydraulically compacted of 3.9 to 4.5.

Description

 Process for the preparation of finely divided solids in the production of chlorosilanes

The invention relates to a process for the preparation of finely divided solids, which in the

Production of chlorosilanes incurred by hydraulic pressing, as well as the process according to obtained compact.

Chlorosilanes such as silicon tetrachloride (SiC, abbreviated STC), trichlorosilane (HS1CI3, abbreviated to TCS) and dichlorosilane (H ₂ SiCl ₂ ) represent an important class of substances with a broad class

They are used as raw material for the production of Si0 ₂ , the so-called fumed silica, as a starting material for organosilanes and silicic acid esters and as reactants for optical waveguides and semiconductor or solar silicon.

It is therefore of the highest technical and economic importance to be able to produce chlorosilanes in large quantities in a cost-effective and safe manner.

Silicon (Si) and hydrogen chloride (HCl) and / or chlorine (Cl) are dissolved in a reactor, e.g. As fluidized bed reactor or fixed bed reactor or stirred bed reactor, which forms inorganic chlorosilanes such as S1CI ₄ and / or HS1CI3 and / or H ₂ SiCl ₂ or mixtures thereof and leave as product gases the reactor and then treated further.

The product gases contain production-related solids such as powder and / or dust containing silicon, iron, iron chloride and / or aluminum chloride. For example, ferric chloride and aluminum chloride are reaction by-products resulting from the fact that the raw silicon used contains these metals in small amounts as contaminants, which remain in the liquid phase after liquefaction of the product gases, the so-called vapors and settle in the container for the liquid phase. As a result, they can be separated from the chlorosilane mixture formed.

Also in a reactor for chlorosilane production above mentioned solids are left behind. Especially in the fluidized bed process for the production of trichlorosilane and

Silicon tetrachloride these solids in the form of powder, dust, for example, filter dust, and / or ash, for example hot gas filter ash on. Such solids are summarized in the context of the invention by the term "/ one-part solids". The particulate solids are mainly silicon and iron, and may also contain chlorine compounds. Together with the chlorine compounds which are gaseous reaction products under the reaction conditions, for example TCS and STC, the finely divided solids are carried out of the reactor.

In the fluidized bed process, ground metallurgical silicon having a diameter of about 500 μm is reacted with hydrogen chloride. During the course of the reaction, the silicon particles become smaller and smaller and can finally exit the reactor as dusts. These dusts are usually separated by means of filters or cyclones before the

 Reaction products TCS and STC are condensed. Because they are very fine and besides iron still contain a large amount of silicon, they are a valuable raw material.

Other silicon-containing solids accumulate in the production of silicon from monosilane by deposition processes. Such solids are often mixtures of product coarse fractions which are separated from the process via sieves, are also analytical residues and goods which do not conform to specifications. The silicon content is often more than 99%.

The patent DE 10 2009 037 155 B3 provides for the dust discharged from the fluidized bed to be converted into a second connected fluidized bed reactor. This method has the disadvantage that the bulk of the solid is discharged due to its extreme fineness also from the second reactor without being materially reacted.

DE 10 2009 020 143 A1 discloses a method for processing sawing waste from wafer production. In this case, sawdust containing silicon and organic compounds are granulated on a granulating disc and are thus to be prepared for further use in chlorosilane production. The saw slurries from which these Si contain

Sawdust or dusts are separated, accumulate as filter cake or suspensions of these wastes in silicone oils or polyethylene glycols. However, the separation of the individual components is complex, and the high proportion of organic compounds in addition to silicon in this stream leads to the formation of many undesirable in the chlorosilane reactors

By-products. In addition, the granules produced from the crystalline material are mechanically unstable and decay quickly. Another way to reconnect the above solids to larger aggregates or pieces is to melt or sinter them. However, the energy required due to the high melting temperatures is disadvantageous.

It was therefore the object to change the finely divided solids such that they can be returned to the Chlorsilanherstellprozess.

The object is achieved by a process for the preparation of finely divided solids and by the compacts obtained according to this method.

The invention relates to a process for the preparation of finely divided solids in the production of chlorosilanes, which is characterized in that the finely divided

Solids are pressed hydraulically to bodies of increased density. The procedure of hydraulically pressing the finely divided solids is in the context of the invention synonymous with the fact that the finely divided solids are pressed in a hydraulic press.

Devices that operate on the principle of hydraulic pressing are the

Specialist known. The advantage of the claimed method is to be seen in the fact that after the passage receives pellets, which can be performed in a simpler way in the production process of chlorosilanes, without having to handle the extremely dusty powder as usual. For example, the compacts obtained according to the invention can be handled by means of conveyor belts or containers and returned to the chlorosilane production process. An air seal, which prevents a dangerous turbulence of finely divided solids, or a complex extraction with filter devices is unnecessary with the implementation of the method according to the invention.

The invention will be explained in more detail below.

In the method according to the invention, it may be advantageous to use a cylindrical sleeve of ceramic, preferably of high-strength silicon nitride ceramic, as press-vacuum. The upper and lower punches of the hydraulic press can be selected from hardened steel be. Preferably stamps can be used in cylindrical form, but also any other shape is possible, for example, edged stamp, which give cube or cuboid compacts, or hemispherical shapes. Since the finely divided solids contain chlorine compounds, the pellets on contact with water or moisture on their surface hydrochloric acid, which decomposes both insufficiently alloyed steel and unpainted components of the hydraulic press. Therefore, the use of a ceramic sleeve is made

Silicon nitride, S1 ₃ N ₄ , as a press vacuum advantageous.

Hydrogen chloride also attacks the mucous membranes, skin and eyes of humans. It is therefore important to ensure that in the case of a manual implementation of the method personal protective equipment is worn, which prevents the direct contact of the finely divided solids used and the compacts obtained according to the invention with skin, eyes and mucous membranes. Preferably, inorganic binders, preferably silicas, aluminates,

Zirconates, calcium oxide, calcium hydroxide, cement, calcium sulfate, binders containing organic compounds, for example silicic acid esters, or a mixture of these binders. If organic binders are used, the organic portion must be removed in a calcination step prior to use in chlorosilane production.

The use of a binder or a mixture of the above-mentioned binder has the advantage of an alkaline pH. Because the solids from the chlorosilane synthesis contain HCl and in the Chlorsilanherstellprozess due to the prevailing reaction conditions

hydrolyzable silicon-halogen bonds, which adhere to the solids, which thus have an acidic pH. This is neutralized by the binder (s). The unpleasant property of the compacts to release hydrogen chloride can thus be at least partially lifted.

It may be advantageous to use a pressing pressure in the process according to the invention which is at most 14 kN / cm ² , preferably from 10 kN / cm ² to 12 kN / cm ² .

Under pressure and pressure in the context of the invention, the pressure above the

Ambient pressure of 1013 hPa at 20 ° C, which is applied to the finely divided solids in the hydraulic press. At a pressing pressure of zero so just the ambient pressure is exerted and thus achieved no compression. At a pressing pressure of at most 14 kN / cm ² surprisingly stable pellets are obtained, because they can be handled, for example, conveyed via a conveyor belt in a reactor for the production of chlorosilanes without breaking or breaking into chunks.

If one chooses the pressing pressure from the interval of 10 kN / cm ² to 12 kN / cm ² , such compacts obtained according to the invention even survive a fall up to 2 m in height, without closing

shatter. This is because these compacts have no inhomogeneous density distribution, equivalent to the fact that the pellets no zones with increased

Density gradients, so-called layers have. The layers can be extended transversely, longitudinally or in any other direction within the volume of the compact and with respect to the direction of action of the pressing pressure and have a non-woven or lens-like shape. The formation of such layers, the so-called layer formation occurs particularly increased above a

Pressing pressure of 14 kN / cm ² on. If the layer formation is avoided, the compacts can be particularly easily returned to the reactor.

In a further embodiment of the method according to the invention, the pressing pressure can be expended by the pressure beginning at zero with a selected one

Press speed is approached. The pressing speed is within the scope of the invention, the quotient of pressing pressure and the time during which the pressure is increased monotonically increasing up to the pressing pressure, synonymous with the fact that the pressing pressure is started during this period.

Preferably, in the method according to the invention, the pressing pressure with a

Pressing speed of 0.1 to 1 kN / cm ² s, preferably from 0.5 kN / cm ² s are approached until the pressing pressure is reached, and then for a period of 0.5 to 1.5 s, preferably from 1 s, and then degraded to zero over a period of 0.5 to 1.5 seconds, preferably 1 second. In the method according to the invention, it is particularly preferred to carry out at least one venting stroke, each venting stroke being characterized in that in the case of at least one initial pressure ρπ which is at most as great as the pressing pressure, this pressure is reduced to a value pi _{f over} a period Δι of 0.5 to 1.5 s, preferably 1 s, preferably to pi _f = 0, and pi _f for a period of time δι from 0 to 1 s, preferably maintained for 0 s, and then the pressure is applied until the pressing pressure is reached.

Preferably, the initial pressure is selected smaller than the pressing pressure. It has been found that when filling a press vacuum with the finely divided solids before starting the pressure, the press vacuum up to 77 vol .-% air or gas. As the pressure starts to rise, the finely divided solids are gradually compressed and the air or trapped gas must escape. However, the smaller the sizes of the particles of finely divided solids are, the longer it takes for trapped air or gas to escape. If at least one venting stroke is carried out in the process according to the invention, compacts having greater strength are obtained than without at least one venting stroke.

Particularly solid pellets are available if in the process of the invention

two aeration strokes a and b are performed, and a at an initial pressure pi _a , with the durations Ai _a and 5i _a , b at an initial pressure pi _b , with the periods Ai _b and 5i _b , and pi _a and pi _{b are the} same or different , are preferably different, and the durations Ai _a and Δ ^ are the same or different, preferably different, and the periods 5i _a and 5i _{b are the} same or different, preferably different.

Each venting stroke can be carried out with or without vacuum, preferably without vacuum, and with 0.2 to 1 kN / cm ² , preferably 0.5 kN / cm ² pressing pressure, and for 2 to 10 s, preferably 5 s duration.

It may furthermore be advantageous, in the method according to the invention, to eject the compact from the press vacuum with an ejection force of 7 to 8 kN / cm ² . The ejection force must be expended to drive the compact from the vacancy. It is known to those skilled in the field of hydraulic presses. Unusual for the result of the hydraulic pressing, however, no noise occurs during ejection.

So there is no jerky force curve when ejecting the compact from the vacancy, with which in the prior art due to the much larger static friction compared with the Sliding friction would count. The known slip-stick effect remains surprising in carrying out the claimed method.

After carrying out the process according to the invention, a surprisingly high fill factor is found. In the context of the invention, a fill factor is understood to mean the ratio of the height at which the press vacuum is filled with the finely divided solids to the height of the compact produced according to the invention. If, for example, the vacancy has been filled up to a height of 96 mm and, after carrying out the method according to the invention, a compact having a height of about 22 mm is obtained, this compact lies with a filling factor of

 96/22 = 4.36

in front. This filling factor is unexpectedly high compared to filling factors of ordinary molding compounds, for example commercial sands, ceramic granules for the sintering for the production of tiles. For example, it is about 2 times lower for pure sand and the same pressure.

Therefore, the subject of the invention is also a compact obtained according to the claimed process and characterized by a filling factor of the finely divided solids to be hydraulically pressed from 3.9 to 4.5.

The method according to the invention is explained in more detail below with reference to examples.

Press trials on finely divided solids from chlorosilane production.

 The finely divided solids were filter dust from the hot filter of a fluidized-bed reactor for the production of chlorosilanes, so-called hot gas filter ash, in the examples described below.

An Alpha 1500 120 hydraulic press made by Alpha Ceramics was used. In this case, a cylindrical 4-hole cylindrical shape DM 41 mm without conical opening was used. Their upper and lower stamps were made of hardened steel, and as

Pressing vacances were used sleeves made of high-strength silicon nitride ceramic (Si ₃ N ₄ ). It was ensured that the mold surface was removed cleanly. If not can be accomplished, can also be pressed with a mirror plate on top. However, then is to be expected with caking of the compact on the contact surfaces.

In the tests, upper punches were entered, entering the mold. Here were these upper punches to align.

Due to the very fine ash was driven with a circulating punch clearance of at most 0.05 mm, as well as a targeted suction used between the lower punches, as at the start of the print was a blowing out of material along the lower punch was observed.

Each press vacuum was filled up to a height of 96 mm with the hot gas filter ash. The tests differed by the pressing pressure, which was 6, 8, 10, 12 or 14 kN / cm ² and each had been started at a pressing speed of 0.5 kN / cm ² s.

The ejection force was 7.5 kN / cm ^{2 in} each case.

The dimensions and densities of the compacts obtained according to the invention are summarized in Table 1.

Table 1. Overview of the determined sizes of the compacts as a function of the pressing pressure.

For each test run at the press pressure noted in Table 1, two bleed strokes were used. The first venting stroke at 2 kN / cm ² pressure was started at 0.5 kN / cm ² s for 4 s, not held, and degraded within 1 s.

The second venting stroke was started at 4 kN / cm ² pressure at 0.5 kN / cm ² s for 8 s, held for 1 s and degraded within 1 s.

It was found that the hot gas bag could hardly be compressed higher than was achieved at a pressure of 14 kN / cm ² . Rather, it was observed that density and

Fill factor as a function of pressing pressure showed a saturation behavior, shown in

Figure 1. If higher compression pressures were used, not shown here, it happened

Layer formation in the compacts.

At a pressure of 10 kN / cm ² to 12 kN / cm ² , the pellets obtained according to the invention withstood a drop from about 2 m in height without shattering. Thus, they had a sufficiently good stability to be able to return them to the reactor.

Claims

claims

1. A process for the preparation of finely divided solids in the production of chlorosilanes, characterized

 that the finely divided solids are hydraulically pressed into bodies of increased density.

2. The method according to claim 1, wherein a cylindrical sleeve made of ceramic, preferably made of high-strength silicon nitride ceramic is used as the press vacuum.

3. The method according to at least one of the preceding claims, wherein a pressing pressure

which is at most 14 kN / cm ² , preferably from 10 kN / cm ² to 12 kN / cm ² .

4. The method of claim 3, wherein the pressing pressure is applied by

the pressure is approached starting at zero with a pressing speed of 0.1 to 1 kN / cm ² s, preferably of 0.5 kN / cm ² s,

 until the pressing pressure is reached, and then

 during a period of 0.5 to 1.5 s, preferably held for 1 s, and then

 during a period of 0.5 to 1.5 s, preferably 1 s, is reduced to zero.

5. The method of claim 4, wherein at least one venting stroke is performed, each venting stroke being characterized

 that at least an initial pressure ρπ, which is at most as large as the

 Pressing pressure, this pressure

 during a period Δι of 0.5 to 1.5 s, preferably 1 s,

is reduced to a value pi _f , preferably at pi _f = 0, and pi _f during a period of time δι from 0 to 1 s,

 is preferably held for 0 s, and then

 the pressure is reached until the pressing pressure is reached.

6. The method of claim 5, wherein

two bleeding strokes a and b are performed, and a at an initial pressure p _la , with the durations A _la and 6 _la ,

b at an initial pressure pib, with the durations Aib and 5ib,

and pi _a and pib are the same or different, preferably different,

and the durations A _la and Aib are the same or different, preferably different, and the durations 6 _la and 5ib are the same or different, preferably different.

Method according to at least one of the preceding claims,

wherein the compact is ejected from the press vacuum with a discharge force of 7 to 8 kN.

Pressing obtained according to the method according to at least one of claims 1-7, characterized by a filling factor of the finely divided solids to be hydraulically pressed from 3.9 to 4.5.