CZ307620B6 - A method for treating a product after flue gas desulphurisation by a semi-dry limestone method and an apparatus for performing the method - Google Patents

Abstract

A method of processing a product which is produced after desulphurisation of the flue gas by semi-dry lime processes and includes treatment thereof and apparatus for carrying out this treatment.

Description

Technical field

The present invention relates to a method for utilizing a product after desulphurization of flue gases with semi-dry lime processes used in thermal energy for the combustion of fossil fuels. The invention therefore falls within the field of thermal energy.

BACKGROUND OF THE INVENTION

The semi-dry flue gas desulphurisation method consists of spraying a water suspension of lime hydrate into a special type of drier, in which the acidic components of the flue gases, such as sulfur oxides, hydrogen halides with calcium salts, react. The water in the slurry is evaporated and passed into the flue gas stream as water vapor. The remaining calcium salts are desulphurization products and leave the dryer as a free-flowing powder. The product thus formed is a mixture of water-soluble and water-insoluble calcium salts. These are sulphates, sulphites, chlorides and fluorides with different contents of bound and free water. The mixture is supplemented with insoluble fly ash inert substances and possibly other impurities. The product resulting from the flue gas desulphurisation is deposited in the hazardous waste landfill. The reason for classifying the desulphurisation product in category N (Waste Catalog) is the leachability of soluble salts. The cost of storing hazardous waste is expensive to operate such a facility.

DE 3331839 C1 describes a method of using gypsum (calcium sulfate dihydrate) obtained in wet flue gas desulfurization for the preparation of α-hemihydrate (CaSO ₄ · Yi H ₂ O). The dehydration is carried out batchwise, at elevated temperature (80-100 ° C) and by the addition of sulfuric acid, which converts the residual limestone or lime hydrate to the necessary sulfate. The formed suspension is filtered, washed with hot water and dried. The resulting α-hemihydrate can be used commercially eg in the construction industry. This method of utilizing the product after desulfurization of the flue gas by the wet limestone method appears to be energy intensive and does not utilize the soluble sulfur and chlorine compounds present in the product.

The aim of the present technical solution is to propose a method and a device enabling complex utilization of products after desulphurization of flue gases by semi-dry lime method including utilization of soluble salts.

SUMMARY OF THE INVENTION

The above object accomplishes a method of utilizing the product after desulfurization of flue gas by semi-dry lime processes involving chemical conversion in a reactor with subsequent filtration. The essence of the solution is that after desulfurization, the product is mixed with water at a temperature of about 50 to 70 ° C in the reactor and any oxidizing agent is added to the mixture. This can be, for example, an air stream which is fed into the reactor while stirring. The oxidizing agent converts the previously unreacted CaSO ₃ salts to CaSO ₄ and then recrystallizes to the dihydrate; CaSO ₄ · 2H ₂ O. Due to the method of preparation, the synonym of gypsum is used for this product. The gypsum slurry is drained for drainage, where the gypsum crystals are separated for use in construction and optionally insoluble impurities are separated from the soluble salt solution.

Furthermore, the separation of soluble salts and the possibility of their further utilization (especially soluble CaCl ₂ salts) are important. The solution of salts, mainly chlorides, is then concentrated in an evaporator. The solid phase of the salt crystals is diverted for use, for example, as a road salt or is intended for further processing in the chemical industry.

- 1 GB 307620 B6

The vapor from the evaporator is preferably condensed. The heat released during condensation is used to heat the reactor and the resulting condensate (hot water) is returned to the reactor to dissolve the crude product after the semi-dry desulfurization method.

The apparatus for carrying out the above method consists of a reactor provided with an input product feed device, a heating device, a mixing device and aeration nozzles. The aeration nozzles serve as the feed of the gaseous oxidation mixture to oxidize the present calcium sulfite to gypsum. The gaseous oxidation mixture may be air or ozone-enriched air. To inject the gaseous mixture, the aeration nozzles are connected to a compressor. After oxidation, the slurry is discharged to the filter, where the solid and liquid phases of the final product are separated, thus there is a separation of the liquid filtrate containing soluble salts and solid phase - crystalline gypsum. The salt solution is then fed to the evaporator from which the vapors are discharged to the condenser via the steam outlet. The concentrated salt mixture leaves the evaporator through an outlet for separated salts. The vaporizer outlet can be connected to a reactor via a condenser.

Clarification of drawings

An apparatus for carrying out the above method is shown in the attached Figure 1.

DETAILED DESCRIPTION OF THE INVENTION

Example 1

Compressed air 6 is supplied to the 220 L reactor 1, under the mixing device 4 via the aeration nozzles 5, from the compressor 6. In addition, 150 liters of hot water are added to the reactor. The temperature of the water is maintained at 60-70 ° C by means of the heating device 3. With constant stirring, 30 kg of the bulk mixture is added to the feed water feed device 2 following the semi-dry desulfurization method. In this case, the mixture contains 63 wt. % CaSO ₃ , 15 wt. gypsum, 8 wt. CaCl _2, 1% by weight. % CaF ₂ , 8 wt. % of fly ash and 5 wt. humidity. After the bulk material is metered in, air is introduced into the slurry through the aeration nozzles 5 as an oxidizing agent. The volumetric air flow is 80 Nm ³ / h. After 30 minutes the slurry is drained onto a vacuum drum filter 7 where the solid phase is separated, melted with hot water and the solid phase of the final product 8, i.e. the filter cake, is dried. The dried filter cake in this case contains 89 wt. sulfates; 1.5 wt. % of sulfites and 9.5 wt. fly ash.

The liquid phase of the final product 8, i.e. the filtrate is concentrated in the evaporator 9 for subsequent crystallization. The vapor vapors from the evaporator 9 are sucked off by the vapor outlet 11 to the condenser 13. The condensate from the condenser 13 is fed to the reactor 1 as part of the hot water to be dispensed. The salt mixture is withdrawn from the evaporator 9 via an outlet 12 for separated salts, whereupon the salts are filtered off and dried. The temperature in the evaporator 9 is maintained at the desired value by external heating 10. The remainder of the mother liquor is returned to crystallization together with the filtrate, i.e. the liquid phase of the final product 8, after isolation of the gypsum gypsum.

Example 2

150 liters of hot water are fed into the same reactor 1 as in Example 1. The temperature of the water is maintained by the heating device 3 at 60 to 70 ° C. While stirring the mixer 4, 32 kg of the bulk mixture is added to the water feed device 2 after the semi-dry desulfurization method. The composition of the bulk mixture is the same as in Example 1. The resulting suspension is gradually

12 liters of 50% hydrogen peroxide were added. After dosing, the mixture is stirred for 10 minutes and then the suspension is drained onto a vacuum drum filter 7 where the solid phase is filtered off, which is further washed with hot water and the final product 8, in the form of a filter cake, is dried in an oven. The dried filter cake does not contain sulphites but, in addition to sulphates, 9.7 wt. fly ash.

The liquid phase of the final product 8, i.e. the filtrate in the evaporator 9, is concentrated to crystallize the sparingly soluble calcium fluoride. The resulting slurry is filtered into calcium fluorite crystals by filtration and the remaining filtrate is used as a base in brine preparation. Fluorite crystals are further used as a coating salt in the thermal treatment of aluminum or its alloys.

Example 3

Compressed air 6 is supplied from compressor 6 to a 220 L reactor equipped with a stirrer 4 in the form of a high-speed stirrer. The reactor 1 is fed with 150 liters of hot water. The temperature of the water is maintained by the heating device 3 at 60 to 70 ° C. With constant stirring, 30 kg of the bulk mixture is added to the warm water by the feed device 2 after the semi-dry desulfurization method. The mixture contains 63 wt. % CaSO ₃ , 15 wt. gypsum, 8 wt. CaCl _2, 1% by weight. % CaF ₂ , 8 wt. % of fly ash and 5 wt. humidity. After dosing the bulk mixture, a mixture of air and ozone is fed to the suspension to oxidize sulfites. The ozone concentration in this case is 2.8%. The gas flow volume is 70 Nm ³ / h. After 30 minutes, the suspension is drained onto a vacuum drum filter 7 where the solid phase is separated, melted with hot water and the final product 8 in the form of a filter cake is dried in an oven. The dried filter cake contains 89 wt. % of sulfates, 1.5 wt. % of sulfites and 9.5 wt. fly ash.

The liquid phase of the final product 8, i.e. the filtrate in the evaporator 9, is concentrated to crystallize the sparingly soluble calcium fluoride. The resulting slurry is filtered into calcium fluorite crystals by filtration and the remaining filtrate is used as a base in brine preparation. The fluorite crystals are further used as a coating salt in the thermal treatment of aluminum or its alloys.

Industrial applicability

The device can be used in all areas of industry where the method of desulphurization of flue gases by the semi-dry limestone method is applied.

PATENT CLAIMS

Claims (4)

Process for treating a product after desulfurization of flue gases by semi-dry lime processes comprising treatment in a reactor (1) followed by filtration, characterized in that the feed product is mixed with water in the reactor (1) at a temperature ranging from 50 to 70 ° C with the oxidizing agent, the resulting slurry is aerated with stirring while stirring, oxidizing in this slurry for the time necessary to convert most sulfites to sulfates to form a final product (8), the slurry of which is drained for filtration in a vacuum drum filter ( 7), where the final product (8) is separated from the suspension and the remaining filtrate is dewatered in an evaporator (9), from which the concentrated salt solution is discharged for further use. -3 CZ 307620 B6 Treatment method according to claim 1, characterized in that the vapor from the evaporator (9) condenses when the heat is recovered in the reactor (1) and the resulting condensate is recycled back to the reactor (1). Device for carrying out the method according to claim 1, characterized in that it consists of a reactor (1) provided with an input product metering device (2), a heating device (3), a mixing device (4) and aeration nozzles (5) which are located at the bottom of the reactor (1), the reactor (1) is connected to a vacuum drum filter (7) with a solid phase outlet of the final product (8) and an outlet for a liquid phase solution connected to the evaporator (9) with outlet (11) for steam and with an outlet (12) for separate salts. Device according to claim 3, characterized in that the steam outlet (11) of the evaporator (9) is connected to the reactor (1) via a condenser (13).