WO1983003619A1 - Process for deashing coal - Google Patents

Abstract

One method of removing carbon from the ash particles is to transport finely pulverized coal by means of a stream of non-oxidizing gas (A), to control the temperature and humidity of the non-oxidizing gas to transport pulverized coal during transport, introduce the gas into an electric dry dust recovery chamber (2) used to trap and separate the ash particles thanks to the difference in intrinsic resistance between the coal particles and the ash particles, and extract extremely pure and finely pulverized charcoal (B) transported by the non-oxidizing gas through an outlet orifice (3) of the electric dry dust recovery chamber.

Description

 Specification

 Title of invention

 Coal demineralization method

 Technical field

 TECHNICAL FIELD The present invention relates to a method for demineralizing coal, and more particularly to a method for efficiently separating ^ components mixed in pulverized coal to obtain pulverized coal with high purity.

 Background art

Most of the pulverized coal is carbon particles, in which particles such as SiO ₂ , CaO, and AI 2 O 3, that is, ash particles, are mixed as foreign matter. When pulverized coal is used as a fuel, the smaller the proportion of the ash particles mixed is, the more advantageous it is. Conventionally, pulverized coal as an object to be treated is put into water. The ash is separated and removed using the lipophilicity of the carbon particles, but the workability is poor with this method. Is difficult to adjust.

Disclosure of Invention ·

 An object of the present invention is to provide a method of demineralizing coal which has good workability and can easily adjust the ash separation accuracy.

In order to achieve this object, the present invention transports pulverized coal as an object to be treated in a stream of non-oxidizing gas, and operates the temperature and humidity of the non-oxidizing gas loaded with pulverized coal during operation. The ash particles are collected and separated by the difference in the intrinsic resistance of the carbon particles and the ash particles in the electrostatic precipitator, and the dry ash is collected. Provided is a method for demineralizing coal that expects to obtain high-purity pulverized coal on a non-oxidizing gas at a dust chamber outlet.

 As the non-oxidizing gas, any of carbon dioxide gas, nitrogen gas and inert gas, or any combination thereof can be used O

 温度 The temperature and humidity of the non-oxidizing gas loaded with pulverized coal should not be preferably adjusted so as to increase the efficiency of separation of ash particles, for example, 10% and 100 ~ respectively. Adjust to 200 ° C.

 The features and effects of the present invention will be clearly understood from the embodiments described below with reference to the accompanying drawings.

Description of drawing

 The drawing is a schematic configuration diagram showing a coal processing system for effectively implementing the present invention.

BEST MODE FOR CARRYING OUT THE INVENTION

In the drawings showing a coal (pulverized coal) treatment system for carrying out the present invention, (1) is a storage tank in which the coal to be treated is charged, and ( ² ) is a storage tank (1). Dry electric dust collector installed downstream, ( ³ ) is a carry-out passage from dry electricity (2), (4) is a blower interposed in the carry-out passage (3), (5) is a dry electric dust collector (2) An inlet passage connecting the inlet of the storage tank (1) with the cut-out opening of the storage tank (1), (6) is a quantitative cut-out device arranged at the cut-out opening of the storage tank (1), ( 7) and (8) are the temperature control device and humidity control device installed in the carry-in passage (5), respectively.

 Confuse.

The loading passage (from one end of the storage tank (1) side of 5), carbon dioxide and nitrogen A medium from a non-oxidizing gas such as gas or inert gas is supplied. Arrow A in the figure indicates the flow of the medium, and pulverized coal that is continuously and quantitatively cut out from the storage tank (1) by the quantitative cutout device (6) is mixed with this medium. Then, the pulverized coal is transported to the dust collecting chamber of the dry electric dust collector on the medium drawn by the blower ( ⁴ ), and the temperature controller (7) is located at a position before the dry electric dust collector (2). The temperature of the medium is adjusted to a predetermined temperature by a humidifier, and the humidity of the medium is increased by, for example, 10% or more by a humidity controller (8), and the medium is carried into the dust collection chamber.

The specific resistance of carbon particles is generally / 0 (: <10 ⁴ [1'111], which is a low specific resistance, whereas the specific resistance Pa of ash particles is generally 10 ⁴

CO - to indicate ^{_{'Cm ^ <Pa <io u}} -Q ^ and intermediate solid' Yes resistance, dry - wherein the electrostatic precipitator (2) collection electrode [FIG ash particles One by the difference in the resistivity of Dewako High purity pulverized coal deposited on the medium is discharged into the discharge passage (3) leading to the outlet of the dust collection chamber. Arrow B indicates the flow of the medium on which the high-purity pulverized coal is loaded. ¾ but your carbon particles also is Tsu by the conditions are once catching collection in the dust collection electrode, carbon particles from the simple task of the inherent resistance of the ash particles to cause a re-scattering phenomenon, the dry electrostatic precipitator ⁽²⁾ Only the ash particles are reliably collected by the collecting electrode, and the collected ash particles flow down the collecting electrode and fall to the hopper (9) of the dry electric precipitator (2). Arrow C indicates emission of ash particles.

 The specific resistance of the ash particles is minimum at about 50 to 60 ° C.) It increases with increasing temperature, reaches a maximum at about 100 to 200 ° C, and gradually decreases at higher temperatures. Temperature control

, G-.PI one

In the device (7), the efficiency of collecting the ash particles in the dry dust (2) is improved by adjusting the temperature of the medium so that the ash particles are large (the specific resistance is reduced). When the humidity in the dust collection chamber is high, the dry electric dust collector (2) can be operated by charging a high voltage, and the humidity of the medium is controlled by the humidity controller (8). Is adjusted and the dry electric precipitator (2) is charged with high voltage for operation. In other words, when the dry type ( ² ) is operated by applying a high voltage, the electric field strength is higher, and thus the dust collection rate is improved and the ash separation efficiency is improved.

 It goes without saying that it is possible to improve the fraction of ash particles by appropriately increasing the number of chambers in the dry electric dust collector (2).

 As described above, according to the method of the present invention, mold powder coal as an object to be treated is transported in a stream of non-oxidizing gas, and the non-oxidizing gas loaded with pulverized coal during transport is transported. The temperature and humidity are adjusted and sent to the dry-type electrostatic precipitator.] The ash particles are collected and separated in the dust-collecting chamber due to the difference in specific resistance between the carbon particles and the ash particles. Since high-purity pulverized coal with non-oxidizing gas is obtained at the outlet of the electrostatic precipitator, the workability of ash separation and removal is good and the separation accuracy can be easily adjusted. In addition, since the dry electric dust collection chamber is filled with a non-oxidizing gas, が it is possible to explode even if a discharge phenomenon occurs regardless of whether dust coal enters the dust collection chamber. It can increase the purity of pulverized coal

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Claims

The scope of the claims  1. Pulverized coal as an object to be treated is transported in the flow of non-oxidizing gas, and the temperature and humidity of the non-oxidizing gas loaded with pulverized coal are adjusted during transportation, and then the dry electric dust collection chamber The ash particles are collected and separated by the difference in the specific resistance between the carbon particles and the ash particles in the electrostatic precipitating chamber, so that the non-oxidizing gas is removed at the outlet of the dry electric precipitating chamber. A coal demineralization method characterized by obtaining finely pulverized coal.  2. The coal according to claim 1, wherein the non-oxidizing gas comprises one of carbon dioxide gas, nitrogen gas and inert gas, or any combination thereof. Demineralization method.  3. The method according to claim 1 or 2, wherein the humidity is adjusted so that the moisture in the non-oxidizing gas on which the pulverized coal is loaded is about 10% or more. Coal demineralization method. '4. The non-oxidizing gas on which the pulverized coal is loaded is heated to a temperature at which the ash particles have a maximum specific resistance, for example, about 100 to 200 ° C.方法 The coal demineralization method according to any of paragraph 3-. -BUREA OMPI Summary Form  The dry coal dust is transported by carrying the coal powder as the material to be treated in the flow of non-oxidizing gas (A), and adjusting the temperature and humidity of the non-oxidizing gas loaded with pulverized coal during transport. Ash particles are collected and separated by the use of the specific resistance between the carbon particles and the ash particles in the electrostatic precipitator (2). (3) A method of demineralizing coal so as to obtain highly pure pulverized coal (B) on a non-oxidizing gas. O? I