RU127744U1 - DEVICE FOR PREPARING MINERAL MIXTURES - Google Patents

Abstract

1. The device for the preparation of mineral mixtures containing a smoke exhaust, bag filter with a collecting conveyor, a feed hopper, a first splitter, a multi-stage cyclone refrigerator, a pressure fan and a storage hopper, the inlet pipe of the smoke exhaust connected to the gas phase outlet of the bag filter, under which the solid phase outlets are installed assembly conveyor, the second output of the first splitter is connected to the input of the solid phase of the multi-stage cyclone refrigerator, and the second output of the pressure fan is connected to the input of the new phase of the multi-stage cyclone refrigerator, and the output of the solid phase of the multi-stage cyclone refrigerator is estrus connected with the storage hopper, characterized in that it includes the first and second rough cyclones, the storage hopper of the dried raw materials, the second splitter, mill-dryer, precipitating cyclone, aeropontane a heater and an airborne calcination furnace, the inlet of the dust and gas mixture of the bag filter connected by a pipeline to the outlet of the gas phase of the second rough cyclone, the inlet of the dust and gas the second coarse cyclone is connected by a pipeline to the gas phase outlet of the first coarse cyclone, the dust and gas mixture inlet of the first coarse cyclone is connected by a pipeline to the gas phase outlet of the mill-dryer, the collecting conveyor and the solid phase exits of the first and second coarse cyclones are connected by flow to the drier of raw materials, the output of the raw material accumulator is connected in estrus with the inlet of the solid phase of the mill-dryer, the inlet of the gas phase of which is connected by a pipeline with the outlet of the gas phase of the cyclone precipitator, the inlet

Description

The invention relates to the field of devices for the preparation of mineral mixtures of non-calcined and fully or partially calcined minerals.

A large family of various devices for the preparation of gypsum binders is known (gypsum materials and products (production and use). Handbook. Under the general editorship of A.V. Ferronskaya. - M .: ASV Publishing House, 2004, 488 pp., Ill. ), such as: apparatus with indirect heating of the material (gypsum boilers and rotary kilns with external heating); apparatuses with direct contact of the calcined material with flue gases (rotary kilns with the passage of gases through the drum cavity and apparatus for firing raw materials in suspension (aerobic mine and ball mills of combined grinding and firing)); autoclaves; self-locking devices; dampers; boilers (reactors).

The disadvantage of these devices is that at the exit from them a calcined material of a given degree of calcination is obtained. By changing the calcination regime, one can change this degree, but it is impossible to obtain a mixture of materials with different degrees of calcination in one technological operation. To obtain such mixtures, it is necessary to either parallelize the process, making simultaneously on different sets of equipment the components of the mixtures with their subsequent mixing, or alternate, making on the same set of equipment, but at different times, materials with different degrees of calcination, accumulating them in bunkers before the next by mixing. Both approaches dramatically complicate the process, increase the cost of equipment, and degrade the quality of the final product.

The closest in technical essence and the achieved result is a device for calcination of gypsum (US patent 4668182). The device comprises: a heater for heating the raw material to be calcined, comprising an input for heating gases, an input for raw materials and an output for heated gypsum; a furnace containing an entrance for heated gypsum connected to the heater outlet, a hot gas generator for at least partially calcining gypsum, an outlet for partially hot calcined gypsum and an outlet for hot gases connected to the heater hot gas inlet; a refrigerator for cooling calcined gypsum, comprising an inlet for a hot partially calcined gypsum connected to an outlet of a furnace for a partially calcined gypsum, an inlet for cooling gases providing heat exchange between the hot calcined gypsum and the cooling gas in the refrigerator in which the hot calcined gypsum is cooled and the cooling gas is heated , outlet for cooled calcined gypsum and an outlet for heated cooling gas, connected to the inlet of the hot water heater Revai gas. The furnace includes a stationary volume, a combustion chamber for preparing hot gases, said volume has a lower inlet for hot gases connected to the combustion chamber, and an upper outlet for hot gases and partially burnt gypsum entrained by them, a gas-particle separator for separating partially burnt particles gypsum from hot gases, closely connected to the outlet of the stationary volume and having an outlet for hot gases, connected to the inlet of the heater for hot gases, and an exit for particles of partially calcined gypsum. The device optionally provides for the recirculation of part of partially calcined gypsum from the outlet of the gas-particle separator of the furnace to the inlet of the furnace for heated gypsum for further calcination. The furnace heater contains at least a pair of sequentially installed gas-particle separators to alternately entrain the raw materials to be calcined and to separate the raw materials from the heating gases. The refrigerator also contains at least a pair of sequentially installed gas-particle separators for alternately dragging the cooling gas from the hot partially calcined gypsum particles and separating the cooled gypsum from the cooling gas. To organize the recirculation of partially calcined gypsum, the device comprises a splitter for unloading portions of partially calcined gypsum from the device. For recirculation of partially burnt gas, a device is provided in the device connecting the outlet of the gas-particle separator to the outlet of the combustion chamber.

The disadvantages of this device are: the inability at the same time to produce a mixture of calcined materials with different degrees of calcination; low operational efficiency due to the fact that the air from the refrigerator enters the heater bypassing the combustion chamber, which requires burning fuel in the combustion chamber with additional costs of combustion air and fuel for heating this air; the high cost of equipment associated with the installation of an excessive number of gas-particle separators in the heater.

The main problem solved by the proposed utility model is the creation of an inexpensive economical device for the preparation of mineral mixtures, which allows at any time to produce a mixture of calcined substances with various degrees of calcination, including non-calcined at all.

This goal is achieved by the fact that the gypsum calcination device uses a multi-stage cyclone refrigerator, an air fountain calcination furnace and an aero-fountain heater, the first splitter installed between the precipitating cyclone of the heated material precipitating the heated raw material, and introducing the raw materials into the air-fired calcination furnace, on the one hand, and input into a multi-stage cyclone refrigerator, on the other hand, and a second splitter installed between the outlet of the dried raw material storage and the inlet of the aero solid phase fountain heater, and storage hopper. Drying of the raw materials is carried out in a combined mill-dryer with a stream of hot gases from the air-fountain heater, and the separation of the dried particles of raw materials entrained by the gases from the mill-dryer is carried out in a dust collector consisting of sequentially installed cyclones and bag filters.

Figure 1 presents the gypsum calcination device. The gypsum calcination device comprises a smoke exhauster 1, a bag filter 2 with a collecting conveyor 3, a feed hopper 4, a first splitter 5, a multi-stage cyclone cooler 6, a pressure fan 7 and a storage hopper 8, the inlet pipe of the exhaust fan 1 being connected to the gas phase outlet of the bag filter 2, under the outputs of the solid phase of which a collection conveyor 3 is installed, the second output of the first splitter 5 is connected to the input of the solid phase of the multi-stage cyclone refrigerator 6, and the second output of the pressure fan 7 is connected to the gas inlet phase of the multi-stage cyclone refrigerator 6, and the output of the solid phase of the multi-stage cyclone refrigerator 6 is connected estrus (not shown) to the storage hopper 8, as well as the first 9 and second 10 primary cyclones, the storage hopper of the dried raw materials 11, the second splitter 12, the mill-dryer 13 , cyclone precipitator 14, aero-fountain heater 15 and aero-fountain calcination furnace 16, wherein the inlet of the dust-gas mixture of the bag filter is connected by a pipe 17 to the outlet of the gas phase of the second rough cyclone 10, the inlet of the dust-gas mixture the second rough cyclone 10 is connected by a pipe 18 to the gas phase outlet of the first rough cyclone 9, the inlet of the gas-dust mixture of the first rough cyclone 9 is connected by a pipe 19 to the gas phase exit of the mill-dryer 13, the conveyor belt 3 and the solid phase exits of the first 9 and second 10 coarse cyclones in estruses (not shown) are connected to the dried raw material accumulator 11, the output of the raw material accumulator 4 is connected in estrus (not shown) to the solid phase inlet of the mill-dryer 13, the gas phase inlet of which is connected by a pipe 20 to the outlet ohm of the gas phase of the cyclone precipitator 14, the inlet of the dusty gas mixture of the cyclone precipitator 14 is connected by a pipe 21 to the output of the aero-fountain heater 15, the input of the solid phase of which is connected by a mechanical feeder (not shown) to the second output of the second splitter 12, the first output of the second splitter 12 connected by estrus (not shown) to the storage hopper 8, and the input of the second splitter 12 is connected by estrus (not shown) with the outlet of the drive of dried raw materials 11, the input of the dust and gas mixture of the aero-fountain heater 15 is connected by a pipe 22 with the exit of the aero-calcination calcination furnace 16, the gas phase inlet of which is connected by a pipe 23 to the first outlet of the pressure fan 7, and the dust-gas mixture inlet of which is connected by a pipeline 24 with the gas phase of a multi-stage cyclone cooler 6, fuel is supplied to the same inlet of the aero-calcination calcination furnace 16 (natural gas), wherein the input of the first splitter 5 is connected to the output of the solid phase of the cyclone-precipitator 14, the first output of the first splitter 5 is connected to the pipe 24 connecting the output of the gas phase of the multi-stage a cyclone cooler 6 with an inlet of a gas-dust mixture of an aero-calcination calcination furnace 16. In a multi-stage cyclone refrigerator 6, the first 25, second 26 and third 27 cyclones and the first 28, second 29 and third 30 pipelines are used, the gas phase outlet of the first cyclone 25 being the gas phase exit of the multistage cyclone refrigerator 6, the first pipeline 28 connects the gas phase outlet of the second cyclone 26 to the inlet of the dust and gas mixture of the first cyclone 25 and is simultaneously connected to the solid phase inlet of the multi-stage cyclone-precipitator 6, in the second pipeline 29 connects the outlet of the gas phase of the third cyclone 27 to the inlet of the dust and gas mixture of the second cyclone 26 and is simultaneously connected to the outlet of the solid phase of the first cyclone 25, the third pipeline 30 connects the inlet of cooling air of the multi-stage cyclone cooler 6 to the inlet of the dust and gas mixture of the third cyclone 27 and simultaneously with the outlet the solid phase of the second cyclone 26, and the solid phase output of the third cyclone 27 is the solid phase output of the multi-stage cyclone refrigerator 6.

In Fig. 1, the directions of motion of the solid phase are shown by solid arrows, and of the gas phase by dashed arrows.

The device operates as follows.

The material to be calcined is accumulated in the raw material hopper 4, from where it is fed by the feeder to the mill-dryer 13. In the mill-dryer 13, free and (partially) crystalline hydrated moisture is removed from the raw material, and the raw material is ground to the required size. Drying of the raw materials occurs intensively in the flow of hot gases coming from the stage of heating the raw materials from the cyclone-precipitator 14. The dried and crushed raw materials are carried away from the mill-dryer 13 by the gas stream and together with it enter the gas purification system. The size of the feedstock taken is controlled by the gas flow rate at the outlet of the mill-dryer 13. Particles larger than the required size are returned to the mill-dryer 13. The size of the raw materials at the inlet of the mill-dryer 13 should not exceed 50 mm. The main fraction of the material after grinding should be in the range from 0.04 to 4 mm. The dryer-mill-dryer can be of various types, designed to work with material with a particle size of 0.04 to 20 mm, for example: tube-dryer, fluidized-bed dryer, air dryer, shaft dryer.

The gas purification consists of the first 9 and second 10 coarse cyclones and bag filter 2, and the pipelines 17, 18, 19 connecting them, and provides a residual dust content of exhaust gas of not more than 20 mg / m ³ . Gases pass through the purification system under the vacuum created by the smoke exhauster 1. If the exhauster 1 is not used, the gases pass through the gas purifiers under the pressure created by the pressure fan 7. Dust particles trapped in the gas purification system (raw flour) are collected in the drier storage device 11.

From the storage hopper of the dried raw materials 11, the raw flour enters the second splitter 12, from where it is unloaded as a suitable product into the storage hopper 8, or is fed by a mechanical feeder to the air fountain heater 15, where it is heated by the exhaust gas heat from the air flow calcination furnace 16. The distribution of the flows of dried raw materials between the first and second output of the second splitter 12 is determined by the position of its regulatory element.

From the aero-fountain heater 15, the gases, together with the material carried away by them, enter the precipitating cyclone 14, in which the heated raw meal is precipitated. At the outlet of the precipitating cyclone 14, the raw meal is divided into two streams using the first splitter 5. One of the streams is fed to the inlet of the solid phase of the multi-stage cyclone refrigerator 6, and the other stream is mixed with the air leaving the gas phase outlet of the multi-stage cyclone refrigerator 6, and together with it, it enters the inlet of the dusty gas phase of the airborne calcination furnace 16. The distribution of the raw meal flows between the first and second outlet of the splitter 5 is determined by the position of its regulating element.

In the aerosol calcination furnace 16, fuel is burned. Combustion air enters the aero-calcination calcination furnace 16 in two ways: part of the air is supplied directly from the pressure fan 7 via a pipe 23 and is pure atmospheric air; the other part comes from the multi-stage cyclone refrigerator 6 via line 24 and contains particles of a solid phase. The solid phase entering the calcination furnace already contains calcined material (which had previously been in the air-fired calcination furnace 16) and not calcined (which had not previously passed through the air-fired calcination furnace 16). The mass fraction of already calcined material in the composition of the solid phase at the inlet to the airborne calcination furnace 16 can vary in the range from 0 to 90%. In the airborne calcination furnace 16, the highest temperatures are reached and the physicochemical transformations in particles of solid material are completed. Gases from the airborne calcination furnace 16 together with the calcined material enter the airborne heater 15.

The flour is supplied for cooling from the cyclone-precipitator 14, standing in the direction of the gases after the air fountain heater 15. Cooling is due to atmospheric air, which is heated, taking heat from the material. In this design, cooling is organized in a multi-stage cyclone refrigerator 6, consisting of sequentially installed cyclones 25, 26, 27. The air in the multi-stage cyclone refrigerator 6 is supplied from a pressure fan 7.

The chilled product from the refrigerator enters and accumulates in the storage hopper 8. There, depending on the operating mode, a part of the dried raw material comes from the first distributor 12. If the product temperature is not low enough, an additional refrigerator can be used in the hopper 8 to complete the product cooling.

The device allows to obtain mixtures of varying degrees of calcined materials, including the simultaneous production of semi-aquatic gypsum and high-calcined anhydrite, one product being obtained at temperatures not higher than 150 ° C and the other as a result of calcination at temperatures above 750 ° C, while analogues allow get only a product with a uniform composition, calcined at the same temperature. This effect is achieved due to the fact that the device includes three thermal units: a mill-dryer, an air fountain heater and an air-fired calcination furnace, each of which has its own heat treatment temperature. At the outlet of the mill-dryer, a temperature of about 120-150 ° C is realized. In the air-fired calcination furnace at the inlet and outlet, the temperature is approximately the same due to the fact that gas combustion (exothermic reactions) and the removal of crystalline moisture occur simultaneously in almost the entire space of the air-fired calcination furnace, and the temperature in the whole volume differs by no more than 100 ° С . The actual temperature in the calcination furnace, depending on the type of raw material to be calcined and the requirements for the final product, can range from 850 to 1100 ° C. In an aero-fountain heater, the temperature decreases from 750-1000 ° С at the inlet to 400-500 ° С at the outlet, averaging about 550-700 ° С. So, the material, which passed only through the mill-dryer and was unloaded from the plant after the second splitter 12, underwent calcination only at 120-150 ° С; the one that got into the airborne heater and was sent to the multi-stage cyclone refrigerator after the first splitter 5 is calcined at a temperature of about 550-700 ° C; and the one that went through the airborne calcination furnace underwent calcination at 850-1100 ° C. In general, the device provides the possibility of obtaining 6 types of products: 3 types of gypsum (semi-aquatic gypsum beta-modification, gypsum anhydrite, estrich-gypsum), metakaolinite (Al ₂ O3 * 2SiO ₂ ), calcium lime; non-calcined mineral powder (passed only a mill-dryer). The combination of the mill and dryer in one mill-dryer device makes it possible to obtain these products with a particle size of not more than 90% -150 microns with a feedstock size of up to 25 mm and an initial moisture content of up to 20% with grinding in one stage (usually this requires 2 grinding stages and 2 drying stages).

A decrease in the number of grinding and drying stages together with a decrease in excess air supply leads to a reduction in the operating costs of the device in relation to prototypes / analogues, and the use of aero-fountain dried instead of a multi-stage cyclone heater, the combination of a mill and a dryer in a single mill _- dryer device, and the possibility of obtaining finished mixtures without the use of additional devices for the accumulation and mixing of fired products reduces the amount of capital costs

Claims (2)

1. The device for the preparation of mineral mixtures containing a smoke exhaust, bag filter with a collecting conveyor, a feed hopper, a first splitter, a multi-stage cyclone refrigerator, a pressure fan and a storage hopper, the inlet pipe of the smoke exhaust connected to the gas phase outlet of the bag filter, under which the solid phase outlets are installed assembly conveyor, the second output of the first splitter is connected to the input of the solid phase of the multi-stage cyclone refrigerator, and the second output of the pressure fan is connected to the input of the new phase of the multi-stage cyclone refrigerator, and the output of the solid phase of the multi-stage cyclone refrigerator is estrus connected with the storage hopper, characterized in that it includes the first and second rough cyclones, the storage hopper of the dried raw materials, the second splitter, mill-dryer, precipitating cyclone, aeropontane a heater and an airborne calcination furnace, the inlet of the dust and gas mixture of the bag filter connected by a pipeline to the outlet of the gas phase of the second rough cyclone, the inlet of the dust and gas the second coarse cyclone is connected by a pipeline to the gas phase outlet of the first coarse cyclone, the dust and gas mixture inlet of the first coarse cyclone is connected by a pipeline to the gas phase outlet of a mill-dryer, the collecting conveyor and the solid phase exits of the first and second coarse cyclones are connected by flow to the drained drive of raw materials, the output of the storage of raw materials is connected estrus with the input of the solid phase of the mill-dryer, the input of the gas phase of which is connected by a pipeline with the output of the gas phase of the cyclone precipitator, the input of the gas mixture of the cyclone precipitator is connected by a pipe to the outlet of the aero-fountain heater, the input of the solid phase of which is connected by a mechanical feeder to the second output of the second splitter, the first output of the second splitter being connected by heat to the storage hopper, and the input of the second splitter is connected by heat to the outlet of the drier feed, the input is dust a mixture of an aero-fountain heater is connected by a pipeline to the outlet of an aero-fountain calcination furnace, the gas phase inlet of which is connected by a pipeline with the outlet of the pressure fan, and the inlet of the gas and gas mixture connected by a pipeline to the outlet of the gas phase of the multi-stage cyclone refrigerator, fuel (natural gas) is supplied to the same inlet of the air-fired calcination furnace, the inlet of the first splitter connected to the outlet of the solid phase of the precipitating cyclone, the first outlet of the first the splitter is connected to a pipeline connecting the gas phase outlet of the multi-stage cyclone refrigerator to the inlet of the gas-dust mixture of the airborne calcination furnace. 2. The device according to claim 1, characterized in that the first, second and third cyclones and the first, second and third pipelines are used in the multistage cyclone refrigerator, the gas phase outlet of the first cyclone being the gas phase outlet of the multistage cyclone refrigerator, the first pipeline connecting the gas outlet phase of the second cyclone with the inlet of the dust and gas mixture of the first cyclone and simultaneously connected with the input of the solid phase of the multi-stage cyclone-precipitator, the second pipeline connects the gas phase outlet of the third cyclone with the input of the dust and gas mixture of the second cyclone and simultaneously connected to the output of the solid phase of the first cyclone, the third pipeline connects the inlet of the cooling air of the multi-stage cyclone refrigerator with the input of the dust and gas mixture of the third cyclone and simultaneously with the output of the solid phase of the second cyclone, and the output of the solid phase of the third cyclone is the output of the multi-stage solid phase cyclone refrigerator.

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