PL170370B1 - Method and device for desulphurization of flue gas using the semi-dry method - Google Patents

Abstract

1. A method of desulfurization of flue gases by a semi-dry method using an aqueous alkaline suspension, in which desulfurization is carried out in the liquid phase in the form of drops rotating in the flue gases and at the same time these drops are dried at a temperature close to adiabatic saturation, characterized in that the dried and partially sulfurized sorbent particles are re-wetted with a sprayed alkaline suspension or water and dried again, after which the dry waste is separated from the flue gases. 4. A device for desulfurization of flue gases by a semi-dry method, designed as a spray dryer, having a conical part and a cylindrical part and a rotating disc, preferably a spray head for generating suspension drops, located at the top in the central point of the cylindrical part, equipped with exhaust gas supply stubs above the spraying disc through swirling guides and exhaust gas and dry waste discharge stubs at the bottom of the device, on the side and in the conical part, characterized in that circumferentially at the top, preferably on the side of the cylindrical part (2), there are located additional spray nozzles (5) directed with a spray cone towards the area near the cylindrical wall (2) and below the disc mounting location (4)

Description

The subject of the invention is a method and device for desulphurization of flue gases with the use of semi-dry aqueous alkaline suspensions, applicable in factory boiler houses, heating plants and small heat and power plants fired with sulphated solid fuel.

The so far known methods of flue gas desulphurization, without sulfur recovery, are based on the use of lime milk sorbent, less often soda, with certain additives regulating the chemical reactions of the process. Lime milk is made of hydrated lime, ground limestone. Known methods of desulfurization consist in contacting flue gases and milk of lime in a reactor of different geometry and milk feeding method. From the point of view of the process, these methods are divided into wet, semi-dry and dry. They are all known processes for numerous industrial applications. Wet methods allow for high desulphurization efficiencies, but the by-product is a troublesome suspension of sulphates and calcium sulphites. These suspensions show a high tendency to incrustation, require special pumps, and the CaSO 3 sludge due to its thixotropic properties cannot be dehydrated below 60-70% of water and therefore it can only be stored in large tanks. Traditional dry methods, while cheap and simple, do not usually provide the required desulphurization efficiencies. The description of the patent application No. WO 089/07974 describes a method of increasing the desulfurization efficiency of the dry method, in particular the use of sorbent, through its appropriate preparation and activation. Semi-dry methods, also known as spray drying methods, combine the advantages of high desulfurization efficiency of wet methods (in both types of methods the chemical process takes place in the liquid phase) with the low cost of dry methods. In the semi-dry method, flue gas desulphurization is performed with the use of an alkaline aqueous suspension fed to the flue gas by means of a rotating disk or nozzles.

The main desulfurization process is carried out in the liquid phase, which is in the form of dispersed swirling droplets in the exhaust gas. These droplets, simultaneously with SO 2 saturation, are dried at a temperature close to adiabatic saturation temperature, so that the end product of the desulphurization process is dry waste. In order for a given semi-dry method to be attractive under the current regulations on environmental protection, it must ensure high desulphurization efficiency, often above 90% with a limited consumption of sorbent. All these methods are one-step. The way to increase the efficiency without increasing the sorbent consumption is to use the two-step method. From US Patent No. 4,753,785, a two-stage desulphurization method is known, which consists in supplementing the traditional dry method, i.e. injecting dry sorbent dust, which is here the first stage, and moistening the atomized dry sorbent with water injected, which is the second stage. This is a significant step forward in increasing the usually low efficiencies of dry methods without excessive, or several times above, the stoichiometric consumption of sorbent. However, the final efficiency is too low for highly sulfurized flue gases, because the method of activating fine dust in the reactor volume with water is inappropriate.

The so-far semi-dry flue gas desulphurization devices of a spray-dryer design consist of a housing having a cylindrical part at the top and a conical part at the bottom, and a rotating disk, preferably a spray head with nozzles for producing suspension droplets. The disk or head is placed in the central part at the top of the cylindrical part. The raw flue gas is usually led above the disc through swirling vanes, and the desulphurized flue gas is led away from the central conical part. On the other hand, dry waste is discharged through a feeder at the bottom of the conical part of the device.

The method according to the invention consists in the fact that the dried and partially sulfurized sorbent particles, still present in the exhaust gas, and formed from the droplets dried at the adiabatic saturation temperature, as in the traditional semi-dry method, are re-moistened with an alkaline spray or water, depending on the given exhaust gas composition. and then they are dried again and then separated from the exhaust gas as dry solid waste. In the method according to the invention, the coarser fraction of waste is discharged separately by gravity, and the lighter, dusty fraction which escapes along with the desulfurized flue gas is separated from the flue gas by one of the known methods. There is a possibility of recirculation of the lighter fraction depending on its composition and after activation by one of the known methods of using it to prepare an alkaline suspension for desulfurization.

In the device according to the invention, additional spray nozzles are arranged circumferentially at the top, preferably on the side of the cylindrical part of the device housing, directed with the spray cone towards the area of the cylindrical wall located nearby and below the place where the disc is mounted. The nozzles are fixed so that the spray cone of the nozzles is parallel to or forms a slight acute angle with the cylindrical wall in the axial direction of the cylinder.

The advantageous effects of the process according to the invention are, first of all, increasing the use of sorbent in semi-dry methods while maintaining or even increasing the desulfurization efficiency. An equally important effect is the increase in the grain size of the dry waste, which facilitates its storage, transport, etc. Additionally, the method according to the invention increases the flexibility of the method for changing the load of desulphurized flue gas in the installation. In the solution according to the invention it is proposed to increase the desulfurization efficiency, similar to the previously described method, by using the second desulfurization stage, but not by developing a dry method, but a semi-dry method. Thus, in the first stage, we can achieve a high degree of desulphurization by spraying the liquid suspension with an insufficient amount of water, so that the droplets dry in the final stage, and the re-wetting, which is the second stage of the process, has an additional task, a slight increase in efficiency, especially in periods of peak exhaust gas flow, without the need to increase the consumption of calcium sorbent, the usual excess is used in relation to the stoichiometry, and only slightly increasing the water consumption. There are a number of detailed solutions here, e.g.

1710370 in the first stage, administer a more diluted suspension, and in the second stage, also this suspension instead of water, using the principle of not increasing the total consumption of lime sorbent, but only diluting it with water. Re-wetting of the partially reacted sorbent also increases the granulation of the dry waste, since the second desulfurization step takes place on the surface of the re-wetted particles, which absorb SO 2 from the flue gas and grow to larger dimensions than in the one-step methods. Most of the waste with larger dimensions means that it can be collected by gravity at the bottom of the desulphurization device itself, to a greater extent than in traditional one-stage methods. This means relieving the bag filter or cyclones downstream of the desulphurization device, which produces less dust secondary dusting with desulphurization products. Nevertheless, still some of the finer waste is collected in the dedusting devices. In order to further increase the degree of sorbent utilization, it is advisable to partially return it to the fresh sorbent suspension preparation section.

The advantageous effects of changes in the structure of the device according to the invention are the increase in the use of sorbent compared to the existing devices by appropriate dosing of the intensity of the supplied suspension of milk of lime and water to different zones of the device in the form of sprayed droplets with different mean Sauter diameter. As it is known, the process of SO2 absorption from the flue gas to a drop of lime milk suspension is intensive only until the drop is dry. The drop must therefore have a significant residence time in the device, but it cannot be too large because it will not have time to dry, which would lead to a wet method with a waste in the form of a suspension. A good solution here is the use of a spraying disk, which produces small drops with a small drop diameter dispersion. This at least makes it possible to obtain a dried product. The droplets, however, dry up too quickly, without exhausting the sorption capacity of the suspension, i.e. they give low values of the conversion degree. These values in running conditions may even be below 25% in relation to the theoretical conversion rate. The device for conducting the process of the semi-dry, two-stage method according to the invention eliminates too fast drying of drops produced by traditional spray disks, preferably nozzle heads, by additional wetting of already dried small droplets - solid particles, with additional nozzles spraying water, preferably lime milk suspension in the form of drops with a large drop diameter dispersion. In addition to the above-mentioned difference in the droplet size, the geometry of the disk foundation in relation to the nozzles is also important. For the disc placed centrally at the top of the device - as for typical spray-droughts, the moistening nozzles according to the invention are placed at the top outer periphery, with the spray cone centrally downwards. For such a geometry, the mean droplet of suspension leaving the tangential spray disk follows the three-dimensional helical trajectory around the axis in consecutive laps lower and closer to the wall, all the way to the outlet at the bottom of the apparatus. It contacts the hot exhaust gases in a cross-flow direction, and then, carried away by the exhaust gas current, it circulates with them and in a short time becomes a dry particle, and then, in cross contact with the droplets flowing out of the nozzles, it moistens and reacts on the surface with the rest residual SO2 still in the flue gas. A typical geometry of the device according to the invention, with marked places for the location of the milk feed, preferably water, is shown in the drawing. The hot sulphated exhaust gas flows through the inlet 1, centrally into the cylindrical part 2 of the device, where it contacts the milk of lime, preferably water, through the supplied line 3 and a spray disc 4, preferably a nozzle head, and the partially reacted sorbent dust carried with the exhaust gas is re-wetted, preferably coated with water sorbent by means of nozzles 5 fed by lines 6, placed circumferentially at the top of the cylindrical part of the device, and after deep desulfurization, the flue gas flows from the conical part 7 of the device through the outlet 8 to the cyclone or bag filter to remove the formed sulphite / calcium sulphate. In addition, a disk, preferably a spray head, supplies air through the line 9 to oxygenate the sulphite formed to sulphate, and a coarser fraction of dried particles is discharged through the port 10.

17 (0370

Example. Raw flue gas, at a temperature of 260 ° C, from a coal-fired boiler, which additionally burns waste gases, with a total expenditure of 120,000 mVh and containing a load of 200 kg SO2 / h, are two-stage desulphurized in one reactor with an efficiency of 90%. To the first stage, 10% milk of lime is fed as a reactant in the amount of 5000 kg / h, and to the second stage, industrial water in the amount of 2000 kg / h , obtaining 800 kg / h of dry coarse waste which is a mixture of CaSO4, CaSO3, Ca (OH) 2, CaC O3, CaCl2, CaF2 and SiO2 with 20% moisture.

170 370

Publishing Department of the UP RP. Circulation of 90 copies. Price PLN 2.00

Claims (5)

Patent claims 1. The semi-dry flue gas desulphurization method with the use of an aqueous alkaline suspension, in which desulphurization is carried out in the liquid phase in the form of swirling droplets in the flue gas, and at the same time these drops are dried at a temperature close to adiabatic saturation, characterized in that the dried and partially sulphated sorbent particles are it is moistened with a sprayed alkaline suspension or water and dried again, then the dry waste is separated from the flue gas. 2. The method according to p. A method as claimed in claim 1, characterized in that the coarser waste fraction which has undergone the re-wetting process is discharged by gravity and the lighter dust fraction is discharged with the flue gas and separated. 3. The method according to p. The process of claim 2, wherein the lighter waste fraction is recirculated and used to prepare the slurry. A device for semi-dry flue gas desulphurization with a spray-dryer design, having a conical part and a cylindrical part and a rotating disk, preferably a spray head for producing suspension drops, located at the top in the central point of the cylindrical part, equipped with exhaust gas connections above the spray disk through swirling vanes and nozzles for the discharge of exhaust gases and dry waste at the bottom of the device, on the side and in the conical part, characterized in that circumferentially at the top, preferably on the side of the cylindrical part (2), additional spray nozzles (5) are arranged, directed with the spray cone towards the area near the wall cylindrical (2) and below the disc (4). 5. The device according to claim 1 4. The spray cone of the nozzles (5) is parallel to or forms a slight acute angle with the cylindrical wall (7) in the axial direction of the cylinder.