FR2580950A1 - PROCESS FOR REMOVING SULFIDOUS GAS COMPOUNDS AND SULFUROUS ANHYDRIDE FROM COMBUSTION GASES OF A FIREPLACE - Google Patents

Abstract

THE INVENTION RELATES TO A PROCESS FOR REMOVING SULFUROUS ANHYDRIDE FROM THE COMBUSTION GASES OF A FIREPLACE. IN ADDITION TO A MATERIAL 4 CONTAINING SULFUR TO BURN AND A GAS 5 CARRIER OF OXYGEN, A PULVERULENT CALCIUM OR MAGNESIUM HYDROXIDE 6 IS PROVIDED IN EXCESS OF THE SULFUROUS ANHYDRIDE GASEOUS PRODUCED IN THE CHAMBER OF COMBUSTION, IN THE COMBUSTION CHAMBER OF FIREPLACE 1, AND WATER 9 OR STEAM IS SPRAYED SEPARATELY IN THE COMBUSTION GAS 8 CARRIERS OF CALCIUM OXIDE OR MAGNESIUM OXIDE THUS OBTAINED, IN A PLACE 2 SEPARATE FROM THE COMBUSTION CHAMBER.

Description

Process for removing gaseous sulfur compounds and

  sulfur dioxide from the combustion gases of a fireplace.

  The present invention relates to a process for removing gaseous sulfur compounds and in particular sulfur dioxide, from the combustion gases of a hearth which burns fuels containing sulfur, by

example of coal or fuel oil.

  It is already known to reduce the sulfur dioxide content of the combustion gases of a hearth, by bringing calcium oxide, calcium carbonate or some other alkaline compound into the combustion chamber of the hearth. In a fluidized bed hearth with a circulating bed, the addition of calcium can reduce the sulfur dioxide content of the combustion gases by a percentage of up to 90 o, when the hearth operates within the optimum temperature range for chemical reactions, i.e. 800 to 1,000.'C. The sulfur dioxide thus absorbed leaves the hearth in the form of gypsum, with the fly ash. In other homes, in which it is necessary to use temperatures higher than those mentioned above, and in which the additive is retained for a short time - due to the nature of the combustion, one should expect that the reduction in the sulfur dioxide content of the combustion gases is significantly less, of the order of 50% or less, and therefore this process has not been applied on a scale

industrial to these homes.

  On the other hand, it is known that the sulfur dioxide content of the combustion gases can be reduced by various absorption methods outside the home. Such a process known per se is what is known as the semi-dry process, in which the combustion gases leaving the hearth are led into a separate reactor, in which an aqueous slurry of hydroxide is sprayed calcium in the form of small droplets through specific nozzles. The reactor is typically a relatively large tank, in which the velocity of the combustion gases is reduced and in which the aqueous slurry is sprayed down from above, from the top of the tank. The temperature of the reactor is at this time around 50 to 80 C and the regulation of the spraying of the aqueous slurry of calcium hydroxide is very important, since too large drops would remain in liquid form on the bottom of the reactor. . The consistency of the aqueous calcium hydroxide slurry must be kept large enough for the calorific content of the combustion gases to evaporate the water entering the reactor so that the absorption product can be recovered as a dry powder. This process removes up to 90% of the sulfur dioxide. The disadvantages of the process are that the nozzles tend to become clogged, in that it is necessary to have an additional apparatus for preparing and dosing the aqueous calcium hydroxide boil, which increases the costs investment, and that regulating the size of

  drops while spraying causes problems.

  The object of the present invention is to provide a process for removing gaseous sulfur compounds such as sulfur dioxide from the combustion gases of a hearth, process by which the gaseous sulfur compounds can be transformed into solid sulfur compounds which can be easily separated from the gases, and thereby effectively removed from the combustion gases of the hearth in a simple and

economic.

  The main features of the invention are set out in

the appended claims.

  In the process according to the inventlon, a material is brought separately into the process which reacts with gaseous sulfur compounds, and in particular with sulfur dioxide, from which it results that the problems of preparation, handling and supply under a slurry are avoided as follows: a) An alkali metal hydroxide and / or a powdery alkaline earth metal hydroxide, in addition to the material containing sulfur to be burnt, and gas containing oxygen, are brought into the hearth or in combustion gases containing sulfur dioxide leaving the fire; b) Water and / or steam are sprayed separately into the hearth and / or into the combustion gases; and finally c) a solid which contains a sulfate is separated from the gases, and

  optionally a sulfite, an alkali metal and / or an alkaline earth metal.

  The basic idea of the invention is thus that the hydroxide is brought into the combustion gases in the form of a powder and is made active only in situ in the combustion gases by means of water and / or vapor, whereupon it reacts with sulfur dioxide and forms a mixture of sulphate and sulphite which can then be effectively removed from the combustion gases by conventional physical ash separation processes. A powdery hydroxide is brought into the combustion chamber of the hearth or into the combustion gases leaving the hearth, depending on the sulfur content of the fuel, so that the amount of alkali metal and / or alkaline earth metal in the molar ratio according to the reaction formula be at least the amount equivalent to sulfur, and

  preferably, however, greater than the amount necessary for the reaction.

  By bringing the hydroxide in the form of powder separately into the combustion chamber or in the flue gas duct, it is possible to use simple supply devices, for example pneumatic devices, and thereby avoids the clogging of the nozzles and the use of additional devices for preparing and dosing an aqueous slurry. In addition, the supply of water and steam by

nozzles is simple and easy.

  The supply of water or steam to the combustion gases is in practice carried out in a temperature range between 50 and 800 ° C., and preferably between 90 and 200 ° C. If it is desired to recover the absorption product practically in the form of a dry powder, only enough water is sprayed so that the thermal content

combustion gases evaporate it.

  The invention is described below in more detail with reference to the accompanying drawing, which schematically shows a device suitable for

  implement the method according to the invention.

  In the drawing, the hearth is identified as a whole at 1. The material 4 containing sulfur to be burnt, an oxygen-carrying gas 5 and a powdered calcium and / or magnesium hydroxide 6 are brought into the combustion chamber of the focus 1, preferably in excess of

  the sulfur dioxide gas produced in the combustion chamber.

  The expression "in excess" means in this context that the amount of the compound of calcium, magnesium or calcium and magnesium is greater than that which would theoretically be necessary, according to the formula of the reaction, to react with the whole of l sulfur dioxide produced

in the combustion chamber.

  The hydroxide brought into the hearth is first dehydrated in it and transformed into oxide. For its part, the oxide can react with sulfur dioxide, first forming a sulfite, and, by subsequent oxidation, a sulfate. Due to the short residence time in the hearth, only part of the oxide has the time to react with sulfur dioxide at a sufficiently high temperature in terms of the reaction, and for this reason the 8-carrier combustion gases of calcium oxide and / or magnesium oxide, which contain combustion residues and vapor, and also unabsorbed sulfur dioxide, leave the

  combustion of the hearth by the combustion gas duct 7.

  In practice, the temperature of the combustion gases 8 is sufficiently low for the reaction between the calcium and / or magnesium oxide and the sulfur dioxide to be relatively weak and, under these conditions, the oxides can be considered as inactive. in terms of sulfur removal. When the temperature of the combustion gases decreases, the oxides can react with the vapor present in the combustion gases and reconstitute the hydroxide. It is thus preferable to bring the pulverulent hydroxide directly into the combustion gas pipe 7 or into the reactor 2 according to the latter. In addition, it is possible to use the combustion gases 8 in the heat exchanger 12 to heat the air 5 to be brought

in foyer 1.

  The combustion gases containing sulfur dioxide, leaving the combustion chamber of the hearth 1 and containing calcium and / or magnesium oxide and optionally calcium and / or magnesium hydroxide, are then directed in a reactor, identified as a whole at 2. In order to make the oxide and / or the hydroxide active, water, or better steam, is sprayed into the combustion gases of reactor 2, and this water or this vapor react with calcium and / or magnesium oxide to form the corresponding hydroxide, making it active and also making the hydroxide active, possibly already present in the combustion gases. For its part, the hydroxide reacts with the sulfur dioxide remaining in the combustion gases 8, thus forming the corresponding sulfite which, in the presence of oxygen at least partially oxidizes

  to give the corresponding sulfate.

  The quantity of water 9 brought into the reactor 2 is adjusted to a value low enough that the heat of the combustion gases 8 is sufficient to evaporate it. The practically dry reaction product similar to fly ash can then be removed in the same way as for other dust in a conventional dust separator 3, from which the combustion gases I 1 are directed into the chimney d exhaust 13 and the separated dust is optionally directed to further processing. The order in which water and hydroxide are added is by no means critical. It is possible, for example, to bring water or steam into the hearth and the pulverulent hydroxide only at a place downstream of the hearth, either in the flue gas duct, or in the reactor which follows it. The method according to the invention also has the advantage that it can be applied to a fireplace fitted with any type of burner. The size of the hearth is not a limiting factor and there is no need to circulate the calcium and / or magnesium hydroxide inside the combustion chamber; this avoids the costly variant with a circulating bed with its complex circulation devices and at the same time the excess of dust due to its operating principle; moreover, we do not have to separate the dust. Compared with the known prior spraying process, spraying water or steam into reactor 2 is considerably less complicated and easier to perform than when using a spray which clogs the nozzles and is difficult to mix. The invention will be described below in more detail using

examples.

Example 1.

  Coal with a sulfur content of 1.4% is brought at a rate of 70 t / h into a 600 MW pulverized coal fire when it is operating at full power. We bring in an excess of combustion air so that the

  oxygen content in the combustion gases, ie 4%.

  Calcium hydroxide having a calcium hydroxide content of 90% is brought into the hearth with varying ratios to the amount of sulfur entering the hearth in the fuel. The theoretical equivalent amount is approximately 2.5 t / h of this calcium hydroxide. Calcium hydroxide and water and / or steam are sprayed into the combustion gases, either in the combustion gas duct or in a

  separate reactor located at a location downstream of this conduit.

  In terms of energy saving, it is more advantageous to increase the moisture content of the combustion gases by spraying the water in these gases in a separate reactor located at a point downstream of all surfaces.

heat recovery.

  The increase in the moisture content of the combustion gases makes calcium hydroxide extremely reactive, from which it reacts quickly with the oxides present in the combustion gases. The higher the moisture content of the flue gases, the more efficient the removal of sulfur dioxide from the flue gases. In terms of energy saving, it is however advantageous to operate in such a way that the heat given off in the chemical reactions is sufficient to evaporate the amount of water added. If we want to increase the final temperature of the combustion gases, we do so, either by using heat

  exterior, either by means of a stream of hot combustion gases.

  The results are shown in the table below, which shows the percentage of sulfur dioxide removed from the combustion gases when varying amounts of calcium hydroxide according to the present invention are brought into the furnace; the amounts of calcium hydroxide are indicated in the form of a molar ratio of the calcium content of the powdered calcium hydroxide to the sulfur content of the fuel arriving in the furnace. The flue gas temperatures are measured immediately before the point of arrival of the water or steam, except for 800 C, in which case the water or steam is brought directly into the fireplace.

Table 1.

  B) Case / S Gas temperature Gas temperature Percentage reduction in combustion combustion 802 A)

0.48 800C 108 C 42%

0.52 50 C 65 C 56%

1.52 202 a C 74 C 77%

1.56 90 C 68 'C 82%

2.20 200 C 72 C 87 Z

2.22 120 C 62 C 96%

2.3 1iO C 68-C 93%

2.5 90OC 66 I0 97%

4.1 800C IIO0 C 72%

4.0 120 C 68'C 98%

  A) Water or steam is brought into the fireplace.

  B) Immediately before the point of arrival of the water.

Example 2.

  Is brought into the hearth according to Example 1, under corresponding conditions, a mixed calcium and magnesium hydroxide which contains 45% calcium hydroxide, 45% magnesium hydroxide and% impurities. The calcium and magnesium hydroxide and the water and / or the vapor are brought into the combustion gases, either in the hearth or

  in a separate reactor located at a point downstream of the hearth.

  The increase in the moisture content makes the calcium hydroxide extremely reactive, from which it reacts

  quickly with the sulfur oxides present in the combustion gases.

  If the molar ratio of calcium in calcium hydroxide to sulfur is at least 1, the reaction takes place mainly between calcium hydroxide and sulfur oxides, and the slower magnesium hydroxide crosses the reaction zone practically without modification. If calcium and magnesium hydroxide is brought into the hot combustion gases, the consequence may be either that the magnesium hydroxide decomposes into magnesium oxide and water, or that all of the hydroxide calcium and magnesium is broken down into calcium oxide and magnesium oxide and water. In this case, each oxide can, as such, react with the sulfur oxides, and, when the combustion gases cool down and the moisture content increases, reform the corresponding hydroxide which subsequently reacts with the sulfur oxides . If the molar ratio of calcium to sulfur is at least equal to 1, the results and the conditions of the reaction practically correspond to the corresponding values in Table 1 due to the ability

  of the calcium compound to react faster.

Claims (5)

Claims.   1. Method for removing gaseous sulfur compounds, for example sulfur dioxide, from combustion gases from a hearth, characterized in that: a) an alkali metal hydroxide and / or a powdery alkaline earth metal hydroxide is brought in (6), in addition to the material (4) containing sulfur to be burned, and gas (5) containing oxygen, in the hearth (1) or in (6 ') in the combustion gases (8) containing l outgoing sulfur dioxide fireplace.   b) water (9) or steam is separately brought into (2) in the hearth (1) and / or in the combustion gases (8), and finally c) gases are separated in (3) (1 1), the solid (12) obtained as reaction product, which contains a sulfate, and optionally a sulfite,   of alkali metal and / or alkaline earth metal.   2. Method according to claim 1, characterized in that the pulverulent hydroxide (6, 6 ') is brought in excess relative to the amount of sulfur   present in combustion gases.   3. Method according to claim 1 or 2, characterized in that the water (9) and / or the vapor are sprayed while the temperature of the combustion gases is between 50 and 800 ° C, and preferably between 90 and 200'C.   4 Method according to any one of claims I to 3,   characterized in that the maximum quantity of water (9) sprayed into the combustion gases (8) corresponds to that which can be evaporated by   the energy produced by the combustion gases and by the reactions.   5. Method according to any one of claims 1 to 4,   characterized in that the hydroxide supplied is calcium hydroxide or a   mixed calcium and magnesium hydroxide.