DE817456C - Process for the production of cyanamides - Google Patents

Description

Process for making cyanamides There are already processes became known to the cyanamides of the alkaline earths, especially calcium cyanamide from the carbonates or oxides with ammonia or with a mixture of ammonia and to produce carbon monoxide.

None of these processes have any practical significance can because of significant difficulties in transferring the laboratory tests stood in the way on the industrial scale.

A way has been found to overcome the previous difficulties largely avoids, namely that the oxides or carbonates of the alkaline earths, mixed with reactive carbon and reaction accelerators to the ammonia gas stream are exposed, despite the use of relatively low reaction temperatures the reaction speed is very fast. The application of solid carbon is much more advantageous compared to the known used carbon monoxide. The carbon is preferably used in a reactive form brought such. B. peat coke, low-temperature coke and types of lignite and hard coal, which at the relatively low reaction temperature is a reactive one Deliver coke. Solid or liquid hydrocarbons are also very suitable, either individually or mixed with coal. When using hydrocarbons, the carbon formed in the course of the reaction is effective.

The halides of Alkaline earths proven to be suitable, such as. B. calcium chloride and calcium fluoride, however, the sulfides may also be suitable. The reaction temperature, which, above all, depends on the pressure under which the procedure is carried out, and depends on the nature and composition of the reactants, is between 400 and z2oo °. It is advisable to keep the response at as deep as possible Temperature, taking advantage of the fast reaction rates at higher temperatures and by taking advantage of the low temperatures in relation to the optimum is determined to reduce the decomposition of ammonia.

By using the carbon as a reactant in solid Form, in contrast to carbon dioxide according to the known process, results in a completely different course of the reaction insofar as, in general, a higher reduction potential is created, which largely prevents the decomposition of ammonia, as This also creates residual gases, which completely replace the ammonia used after adding elemental nitrogen. The following reaction equations should illustrate this.

Course of the reaction according to the known method CaC0g + 2NHs = CaCNa + 3H20 or when using quick lime Ca0 + 2C0 + 2NHs = CaCN $ + COq + HQ0 + 2H2. In contrast is the use of solid carbon is beneficial because carbon oxide already represents the first combustion stage of carbon, so only still has half the reducing power. The reaction equations run accordingly according to the present process mainly as follows: CaO + 2C + 2NH3 = CaCN2 + C0 + 3H2 respectively.

2Ca0 + 3C + 4NH9 = 2CaCNs + C02 + 6H20 or when using carbonate CaCOg + 3C + 2NH $ = CaCN2 + 3C0 + 3Ha respectively.

2CaC03 + 3C + 4NHs = 2CaCN2 + 3C0z + 6H2. From this juxtaposition goes shows that the consumption of chemical raw materials compared to the azotization previously known process is significantly lower (coal, instead of obtained from this Carbon oxide) and the hydrogen requirement for one switched into the gas cycle Ammonia synthesis can be covered from the reaction gases themselves.

In addition, there is even excess CO, which, according to the equation CO + Hz0-Hz + CO, converted with the directly formed hydrogen of reaction together, delivers more H. than is necessary to replace the consumed NH3, so that any losses are also covered can.

As is well known, the main part of the production costs for synthetic Ammonia is used in the production of hydrogen, forms the present process in Combination with an ammonia synthesis a very economical production method for calcium cyanamide.

The reaction gases from the azotization process, possibly also the Hydrogen obtained by the conversion of carbon monoxide are therefore of Carbon oxide and any impurities freed in the usual way and with elemental Nitrogen as a replacement for the nitrogen bound during the azotization of an ammonia synthesis fed. The ammonia obtained in this way is used for a new azotization, thus the cycle of hydrogen and any decomposition products of the Ammonia is closed. The hydrogen in the cycle thus represents represents the nitrogen carrier for the azotization. The process can be continuous be performed. The raw materials for this are ultimately lime, coal and more elemental Nitrogen, the usual one associated with an extraordinary expenditure of energy Way over the carbide is avoided. The azotation process offers particular advantages and to carry out the ammonia synthesis under the same and higher pressure, because thereby the decomposition of the ammonia is practically completely eliminated and so is the compression of hydrogen is eliminated. For most of the gas volumes is only a circulation pump is required and only the nitrogen bound during the azotization to replace and to compress to reaction pressure.

The carbon dioxide and any impurities are washed out also here in the usual way.

As already mentioned at the beginning, this is also the case with pressureless azotization the decomposition of ammonia through the use of solid reactive carbon largely avoided compared to the previously known processes, but not yet completely switched off.

It is particularly useful to carry out the azotization in the presence of hydrocarbons carry out, because these protect the ammonia from decomposition, deliver hydrogen and give off solid carbon by decomposition, which in the sense of the present Invention for Azotierung is effective, in such a way that even if Hydrocarbon is used, from the separate addition of the reaction carbon can be disregarded.

Instead of hydrocarbons, other ammonia can also be used suitable diluent gases are added, such as. B. nitrogen or hydrogen. Depending on the consistency of the hydrocarbons to be used, these can also be the solid reaction components are added.

Since it is the binding of the ammonia to the oxides or carbonates the alkaline earth is an endothermic process, it may be from Advantage of coupling this with an exothermic process. An excellent example offers the production of calcium cyanamide from calcium carbide and elemental Coupled with the production of calcium cyanamide from lime, coal and nitrogen Ammonia. In this process, a mixture of finely ground technical Carbide with or without added carbon and an addition of reaction accelerators, such as calcium chloride or calcium fluoride or a mixture of these two, with the help a gas mixture consisting of elemental nitrogen and ammonia, azotized, tests have shown that most of that contained in the raw carbide excess calcium oxide has been properly converted into calcium cyanamide. The advantages of such a combined method are as follows: e.g. The production an existing calcium cyanamide plant can be significantly improved with the same carbide base increase; 2. the heat demand of the Azotation via calcium oxide is covered by the heat of azotization of the carbide and therefore no cumbersome one is required External heating of the reaction ovens are used; 3. that contained in each raw carbide Calcium oxide is also used to form cyanamide and is not needed separately be won; 4. The one involved in the conversion of calcium carbide into calcium cyanamide The carbon released is also used to form cyanamide from calcium oxide. Example i 56 parts of technical calcium oxide are mixed with 18 parts of low-temperature coke mixed from a gas flame charcoal and 15 parts of dehydrated calcium chloride and pulverized, after i 1/2 hour passing ammonia gas over it at a temperature of 750 ° C an end product with 21.12% N content, namely in the form of calcium cyanamide, is formed. Example 2 A mixture consisting of 56 parts of technical calcium oxide, 24 parts Gas flame coal, 10 parts technical calcium fluoride and 10 parts technical calcium chloride, gives an end product with 19.46 ° / 0 after passing ammonia gas over it at 650 ° C. for 1 hour N content in the form of calcium cyanamide. Example 3 85 parts of a technical regrind, Consists of 63% calcium carbide, 2.96% N in the form of technical calcium cyanamide and about 10% calcium fluoride, which is normally used for azotization to produce calcium cyanamide with gaseous nitrogen use is made with 15 parts calcium chloride mixed and with a gas, mixed, consisting of 2 parts by volume N2 and 1 part by volume Ammonia, azotized. The reaction temperature was 85o °, the reaction time 2 hours. The result was calcium cyanamide with a N content of 22.49%.

The same mixture gives a much lower yield with nitrogen gas alone, and even with a 100% conversion of the calcium carbide present to calcium cyanamide -1- carbon, the yield obtained or the N content could not be achieved, which is proof that that the admixed ammonia has reacted in the sense of the examples already mentioned. Example 4 A hybrid, consisting of 56 parts of technical Calciunloxyd, 24 parts of peat coke and 15 parts of dehydrated, technical calcium chloride, gives, after il / "hour passing a gas mixture consisting of 95 parts by volume of ammonia and 5 parts by volume of benzene at 700 ° C a final product with 19.85% N content in the form of calcium cyanamide.

Example 5 A mixture consisting of 56 parts of technical calcium oxide and 15 parts of dehydrated, technical grade calcium chloride, with 25 parts of bitumen intimately mixed and shaped into pellets, after 2 hours of passing over NI-I. gas at a temperature of 750 ° C is an end product with a 20, 10 /, N content in the form of calcium cyanamide.

Claims (12)

PATENT CLAIMS: i. Process for the preparation of cyanamides of the alkaline earths, in particular calcium cyanamides from the carbonates or oxides of the alkaline earths with ammonia, characterized in that the reaction of the alkaline earth compounds is carried out in the presence of solid reaction carbon and reaction accelerators. 2. The method according to claim i, characterized in that one is used as the reaction accelerator Halides of the alkaline earths used. 3. The method according to claim i and 2, characterized characterized in that the ammonia to be supplied is admixed with a diluent. 4. The method according to claim i to 3, characterized in that the to be fed Ammonia mixed with nitrogen. 5. The method according to claim i to 4, characterized in that that the ammonia to be supplied is admixed with hydrogen. 6. The method according to claim i to 5, characterized in that hydrocarbon is added to the ammonia. 7. The method according to claim i to 6, characterized in that the reaction carbon only in the form of hydrocarbons, solid or liquid, added. B. procedure according to claims i to 7, characterized in that the reaction is released converting hydrogen to ammonia with freshly supplied nitrogen and this used for azotation. 9. The method according to claim i to 8, characterized in that that in the reaction released carbon oxide with steam to carbon dioxide and hydrogen and converts this with nitrogen to ammonia. ok Procedure according to Claims i to 9, characterized in that the cyanamides are produced from the alkaline earth compounds with an exothermic process. ii. procedure according to claims i to io, characterized in that the production of the cyanamides from the alkaline earth compounds with calcium cyanamide production from calcium carbide clutch. 12. The method according to claim i to ii, characterized in that the preparation of the cyanamides from the alkaline earth compounds is carried out under increased pressure, primarily under the pressure required for the ammonia synthesis.