SE429010B - SET TO CLEAN A HEAT GAS FROM SULFUR DIOXIDE OR OTHER NON-REQUIRED SURA GAS COMPONENTS AND DEVICE PERFORMANCE - Google Patents

Description

7908673-2 2 the second step. Both textile filters and electric filters of conventional types are used as dust collectors.

The present invention relates to an improved method of separating sulfur dioxide from hot flue gas which provides high efficiency, is reliable while requiring low investment cost compared to previously known methods.

This is achieved by a method which appears from the features of claim 1. In the method according to claim 2, a further improved separation is obtained. The characteristics of the device are apparent from the features of claim 3. The invention is based on the surprising discovery that the drying step and the separating step can be performed in an integrated chamber, in contrast to known methods where separate apparatus units have always been used for the process. The reason for this is mainly due to the fact that the risk of clogging of the filter material is judged to be very great, if an aqueous absorbent were to be added directly to the filter chamber, which could then be assumed to give a strongly increased gas resistance across the separator. According to the invention, nozzles or other means for atomizing the absorbent are placed inside the filter chamber itself, in such a way that incoming hot gas rewinds them and is directed so that the mixture of liquid droplets and cooled gas does not directly reach the filter medium without first flowing freely in the chamber for a period of 1 - 15 seconds. The main part of the water in the injected absorbent evaporates, a certain residual moisture remains in the dust even after it has been separated on the filter medium.

It has further surprisingly been found that a high content of residual moisture can be accepted in the separated dust without any inconveniences having been observed in the form of an increased pressure drop across the filter. In these experiments with a device of the type provided, even the liquid dosing has been deliberately pushed so far that the filter medium has been completely wet without the feared inconveniences being observed. Contrary to what could be assumed, the permeability does not appear to be adversely affected by the moisture present. 7908673-2 As a result of the fact that a higher moisture content in the dust can be accepted, a considerably higher degree of separation of SO2 can be expected in the system according to the invention. Experiments have shown that in the case of flue gases from burning charcoal sulfur, the degree of separation can be increased from about 75% to about 92% by operating the process at a higher moisture content in the dust in the filter. The invention also entails a significantly reduced investment cost compared with conventional technology, as only one chamber needs to be built, with the significant savings this entails for steel structures, stairs and walkways, and not least insulation.

The invention will now be described in more detail in connection with the accompanying drawing figure, which schematically shows a device according to the invention. In the figure 1 is a filter chamber to which the hot flue gas is supplied through a gas inlet 2. At its transition to the chamber an atomizing device 3 is arranged and the absorbent in the form of an aqueous solution or suspension in water is supplied thereto through the liquid line I The filter chamber 1 is a textile barrier filter 6 arranged in the form of a number of filter hoses 7. The space between gas inlet pipe 2 and the barrier filter 6 forms the reaction chamber V, in which reaction between the absorbent and the sulfur dioxide in the flue gas takes place during drying of the reaction products. The chamber part V is so dimensioned in relation to the flue gas flow Q that the average residence time of the flue gas in the chamber part V is between 1 to 15 s. The ratio between the volume of the chamber part V in Ä and the flue gas flow Q in Å / s is thus between 1 and 15 ( s). By arranging the atomizing device 3 at the transition of the gas inlet 2 to the chamber V, an efficient mixing of the supplied absorbent in the flue gas flow Q is obtained. the filter material and leaves the filter chamber 1 via the cleaning outlet 8, where also means 9 for the cleaning of the hoses are arranged. Under the filter hoses 7, bottom pockets 10 are arranged for collecting the separated dust, which is then discharged through the locking apparatus 11. The invention will now be further elucidated by the following application examples. A gas flow of about 15500 Å / h and the temperature 148 ° C was fed to a test device which consisted of a modified hose filter, from which hoses were removed so that a void was created in the middle of the filter chamber. The height of the filter was about 6.5 m and its cross section was square 2.3 x 2.3 m. The filter contained a total of 75 filter hoses, corresponding to a filter surface of 15QÄ. The gas was introduced through the roof of the filter chamber into a vertically arranged channel which opened about 0.2 m below the roof of the filter chamber. At a level with this, a nozzle of conventional two-media type was placed. The input sulfur dioxide content was measured to be about 500 ppm. At the addition of about 6.5 l / min of an approximately 4% suspension of calcium hydroxide, the outgoing sulfur dioxide content dropped to about 75 ppm, at an outgoing gas temperature of 75 ° C. The pressure drop across the filter varied between 102 and 118 mm water columns, depending on the cleaning of the filter hoses, which was done with the help of compressed air.

The invention has been described above in connection with the separation of sulfur dioxide from a gas stream. However, the invention is not limited to this, but within the scope of the appended claims it is also applicable for the separation of other undesirable acid gas components.

Claims (3)

r 7908673-2 P A T E N T K R A V A method of purifying a hot flue gas from sulfur dioxide or other undesirable acid gas components by contacting the absorbent in the form of an aqueous solution or suspension in water with the flue gas while drying the reaction products formed by the absorbent and the sulfur dioxide and then separating the reaction products in a textile barrier filter, characterized in that the absorbent is introduced into a filter chamber (1) in finely divided form and mixed into the flue gas stream (Q) supplied to the filter cube and that the mixture is given a residence time in the filter chamber (V) of between 1-15 s during almost complete surface evaporation of the reaction products, after which the flue gas stream is caused to penetrate the filter material of the filter (6) arranged in the filter chamber during deposition on the filter material (7) of the reaction products formed. 2. A method according to claim 1, characterized in that capillary bound water is caused to evaporate from the reaction products after its deposition on the filter material (7) during further reaction between the remaining sulfur dioxide in the shrimp, the absorber and the liberated water. Device For purifying a hot flue gas from sulfur dioxide or other undesirable acid gas components comprising a reaction chamber (V) with inlet for the gas and an atomizing device (3) For supplying an absorbent in the form of an aqueous solution or suspension in water to the flue gas in the reaction chamber (V) and a filter chamber (1) with means (6) for separating the reaction products formed from the gas, characterized in that the reaction chamber (V) is integrated in the filter chamber (1) in which the separating means consist of textile barrier filter (6 ) and that the volume of the reaction chamber (V) between the gas inlet (2) and the filter material (7) is dimensioned so that the flue gas flow is imparted to an average residence time of between 1 and 15 in said chamber part (V).