DE1471569B - Process for the production of ashless coke from coal. Eliminated from: 1421272 - Google Patents

Description

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The presence of fiber carbon, mineral substances (analyzed as ash) and bound Sulfur is the main reason why coal is unsuitable for making coke, which is used for Manufacture of anodes is suitable. Sulfur is generally in the form of organic in coal Contains sulfur compounds, as pyrite and / or as inorganic sulfate. It is known that the Ratio of inorganic sulfate and pyrite to organic sulfur in coals with increasing total sulfur content increases.

A number of methods are already known to reduce the fibrous carbon content in coal or mineral charcoal and mineral substances or ash.

A process for coal extraction is known under the name Pott-Broche process, which is e.g. U.S. Patent 1,881,927. After that, a charcoal extract is made by treating one Partly made of carbonaceous material, such as hard coal, lignite or peat, with two parts tetralin manufactured to operate at a temperature of 320 ° C to 400 ° C and a pressure of about 100 atmospheres to form a solution from the coal. The minimum temperature during the extraction is the temperature used as the starting material due to the decomposition temperature Coal for sure. The insoluble and dissolved particles are removed from the solution by centrifugation separated. The tetralin is then distilled off from the solution to obtain a charcoal extract, which has a smaller percentage of ash than was originally present in the raw coal. the Separation of the undissolved and insoluble particles from the solution was later carried out more effectively, by passing the solution through a variety of ceramic filters. The loss of Solventing during separation is one of the disadvantages encountered with these separation processes. They also exist in other processes for separating fiber charcoal, ash or similar impurities out of solution. Another problem is the coking according to different stages of the process during extraction and separation.

In US Pat. No. 2,166,321, Pott describes a process for using the coal extract obtained in the above-mentioned process to produce a semi-coke or high-temperature coke. The semi-coke or high-temperature coke is produced by mixing the coal extract with a semi-coke, which is obtained beforehand in the process, by charging a coking furnace with the resulting mixture. The mixture is heated in the coker furnace to a temperature of 450 ° C to HOO ⁰ C to produce char or Hochtemperaturkoks, depending on whether a low or high temperature is maintained in the furnace. The coke produced in the coking furnace had a low ash content and was suitable for use as coke for making electrodes.

From U.S. Patent 2,686,152 there is a method of making a solid, coherent coke by extracting coal in the presence of hydrogen with a solvent from aromatic Hydrocarbons, which can also split off hydrogen, as well as at elevated temperatures and if necessary known superatmospheric pressure. The solvent is then distilled off, and the extract with the residue is finally treated by heating in the absence of air to drive off the volatile constituents, coked. The aromatic solvents used are tetralin (K.P. 206 ° C), cresol (K.P. 190 ° C to 202 ° C), Anthracene (K.P. 35 Γ C), hydrogenated chrysene (K.P. 373 ° C), phenanthrene (K.P. 340 ° C), chrysene (K.P. 448 ° C) and decalin (K.P. 185 ° C). In this process, during the first extraction stage considerable amounts of hydrogen, for example hydrogen of 70 at at a temperature of 440 ° C, used. However, the coke produced by this process is not ash-free and is therefore suitable not for the manufacture of anodes.

It is an object of the invention to provide a new process for the production of practically ashless coke and Extraction of valuable components from coal, such as gas, aromatic solvents and oils and Ammonia, to indicate, according to which a solution of bituminous coal, sub-bituminous coal or lignite is coked in an organic solvent.

In particular, a cyclical process by coking a deashed solution of carbonaceous is desired Substances, being the vaporous products recovered from the coking unit will provide at least part of the solvent required for the preparation of the solution of the carbonaceous substance is required.

The invention relates to a process for the production of practically ashless coke by Coking of a by dissolving coal in an organic solvent with a high content of aromatic

matic hydrocarbons and with a boiling point charcoal extract obtained above 343 ° C, which has been freed from the insoluble constituents, with simultaneous recovery of solvents from the liquid distillation products, which thereby is characterized in that a fraction of the distillation products obtained is used as a solvent in whole or in part and the coal extract before the Coking to a temperature above the incipient coking temperature of the coal in the coal solution is preheated from 455 to 566 ° C.

The invention is to be explained in more detail on the basis of a general exemplary embodiment:

Bituminous or sub-bituminous coal or lignite and / or a mixture thereof are ground or pulverized state continuously. brought into a dissolving tank, in which a pressure between 1 and 8 atmospheres prevail. A conveyor guides the coal into the dissolving tank or Dissolving tank without loss of pressure.

The highly aromatic, high-boiling liquid solvent is introduced into the dissolving tank in an amount that results in a ratio of solvent to carbon between V ₂ : 1 to 6: 1, the dissolving tank is at a temperature between 315 ° C and 450 ° C, preferably between 400 ° C. and 440 ° C., and above the final decomposition temperature of the coal used as the starting material, as a result of which a substantial part of the extractable carbonaceous material in the raw coal is thermally depolymerized. The products of the depolymerization are soluble in the highly aromatic solvent.

Since the solvent can have an initial boiling point (converted to one atmosphere) of only 344 ° C, while the solution temperature can be 455 ⁰ C, the dissolving tank is provided with a vent line to allow the lowest boiling components of the solvent to be removed and from to enable other volatile substances emitted by the raw coal. A practically uniform coal solution, in which undissolved and insoluble solid substances are suspended, which contain the mineral charcoal and mineral substances or ash, is drawn off via a discharge line located at the bottom and passed on via a cooler to a continuous rotary filter.

The carbon solution is cooled to a temperature between 205 ° C and 371 ° C as it passes through the condenser. The filter is normally operated at a pressure of about 2.8 to 4.2 kg / cm ² to effect effective removal of virtually all suspended solids, including undissolved carbonaceous material. The filter cake is washed and dried to recover absorbed solvent.

The carbon solution is then in a heat exchanger to a temperature between 455 ° C and Heated to 566 ° C and passed to a coker where the batch decomposes into coke and gaseous products will. The ash from the coal solution can be treated in a conventional coking unit, which is roughly the same as the units used for coking petroleum and in the the solution is heated to a temperature above its initial coking temperature and thereafter is coked to produce practically ash-free coke, which has a large proportion of highly volatile Contains substances, e.g. from 4 to 16%.

The coal solution can also be used in a contact coking unit, which consists of a reaction vessel, which has a downward flowing bed of finely divided, heated material on which the batch is spread and is coked, treated at a higher temperature to obtain coking products which less than 6% volatile substances. contain. Higher

ίο Temperatures are allowed because of the Fluidized bed arrangement does not require the removal of coke levels less than 6% volatile matter consists of a drum. Also require the methods with the contact coking no separate preheating of the batch to a temperature above its initial coking temperature, since the batch is in the coker itself due to the easily adjustable temperature of the contact particles to a temperature above the initial Coking point can be brought.

The withdrawal of the gaseous components from the coker is fed to a fractionation unit, which is provided with fractionation floors. Introducing the exhaust into the fractionation tower can cause foaming cause. This can be done in a known manner by adding a small amount of an antifoam agent be prevented from occurring at the point of introduction or at a higher point in the Tower is added. By controlling the pressure and temperature in the tower, the distillation fraction possesses in the line an initial boiling temperature (converted to one atmosphere) between 340 ° C and 450 ° C and represents all or part of the solvent used to dissolve or digesting the extractable carbonaceous material in the pulverized feed raw coal is used.

The demands placed on the solvent when processing bituminous coal can generally be satisfied by operating the fractionation unit in such a way that a distillate results, that has an initial boiling point (converted to one atmosphere) of around 400 ° C. If additional solvent is required (in addition to the distillate which passes over 400 ° C), the fractionation unit can be operated so that a distillate results, which is an initial . Boiling temperature (converted to one atmosphere) of only 343 ° C. If so desired is, the fractionation unit can also be operated so that the latter distillate under Removal of excess solvent that is not necessary for the requirements in the dissolving tank are recovered for use in other process steps.

The following examples are intended to further illustrate the invention.

example 1

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According to the invention, there was made a bituminous coal having the following composition

Analysis weight percent

Moisture content 1.4

volatile substances 36.6

solid carbon 56.6

Ashes 5.4

comminuted to such a particle size that 37.3% retained on a sieve of 0.147 mm mesh size became. It was found that the amount of bound sulfur was 1.46 percent by weight. The coal and a tar distillate that has an initial boiling temperature of around 400 ° C (converted to one atmosphere) were introduced into the dissolving zone, with a ratio of solvent to Coal of 3: 1 was adhered to. The mixture was stirred, cooled to the temperature of 232 ° C and passed through a filter. The filtered carbon solution was then heated to 488 ° C. and closed coked with a coke with the following composition:

Weight percent

Volatile substances' 10.9

Sulfur. 0.27

Ash 0.13

Iron 0.036

Silicon 0.009

R ₂ O ₃ (R = metal) 0.112

Nickel 0.0073

Titanium 0.013

Vanadium 0.00024

Boron (ppm) .-

Example2

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After the preparatory work mentioned in Example 1, a bituminous coal with the same properties possessed like the coal in Example 1, and a distillate that had an initial boiling point (converted to an atmosphere) of about 400 ° C, introduced into the zone in the dissolving tank, with a The ratio of 2: 1 between solvent and charcoal was observed. The mixture was stirred while maintaining a pressure of 5 atmospheres and a temperature of 427 ° C. The resulting charcoal solution was brought to a tempe

Temperature of about 233 ⁰ C cooled and passed through a filter.

The filtered coal solution was heated to 488 ° C and turned into a coke of the following composition coked:

Weight percent

Volatile substances 6.5

Sulfur.; .... 0.28

Ash 0.12

Iron 0.025

Silicon ........ 0.003

R ₂ O ₃ (R = metal) 0.096

Nickel: 0.0015

Titanium .... 0.014

Vanadium 0.00024

Boron (ppm) 10

The quality of the coke produced according to the above examples corresponds to that of coke, which has been made from the best petroleum residues.

The discharge from the coker was condensed and had the following properties or the following additions composition:

Specific weight (density of the substance at temperature T / density of water at temperature T ₂ )

(100/60 ° F) 1.148

(25/25 ° C) 1.160

Viscosity at 99 ° C (centipoise),. 12.0

Conradson carbon (weight percent) 0.18

Sulphonation residue ... none

Sulfur (weight percent) 0.38

Before the coker was withdrawn, about 50% had an initial boiling point greater than 400 ° C.

Claims (3)

Patent claims: 1. Process for the production of practically ashless coke by coking a through Solution of coal in an organic solvent with a high content of aromatic hydrocarbons and with a boiling point above 343 ° C obtained charcoal extract, that of the insoluble Components was freed, with the simultaneous recovery of solvents from the liquid distillation products, characterized in that the solvent is whole or partially used a fraction of the distillation products obtained and the coal extract before coking to a temperature above the incipient coking temperature of the coal in the coal solution is preheated from 455 to 566 ° C. 2. The method according to claim 1, characterized in that the vapors leaving the coking device to obtain a heavy distillate with an initial boiling point between 340 and 450 ⁰ C, preferably 400 ° C, are fractionated. 3. The method according to claim 1 or 2, characterized in that the coal extract in one Contact coking device coked and released in this device by the contact material Heat is preheated. 30th