Principles Most FGD systems employ two stages: one for
fly ash removal and the other for removal. Attempts have been made to remove both the fly ash and in one scrubbing vessel. However, these systems experienced severe maintenance problems and low removal efficiency. In wet scrubbing systems, the flue gas normally passes first through a fly ash removal device, either an electrostatic precipitator or a baghouse, and then into the -absorber. However, in dry injection or spray drying operations, the is first reacted with the lime, and then the flue gas passes through a particulate control device. Another important design consideration associated with wet FGD systems is that the flue gas exiting the absorber is saturated with water and still contains some . These gases are highly corrosive to any downstream equipment such as fans, ducts, and stacks. Two methods that may minimize corrosion are: (1) reheating the gases to above their
dew point, or (2) using materials of construction and designs that allow equipment to withstand the corrosive conditions. Both alternatives are expensive. Engineers determine which method to use on a site-by-site basis.
Scrubbing with an alkali solid or solution is an
acid gas, and, therefore, the typical sorbent slurries or other materials used to remove the from the flue gases are alkaline. The reaction taking place in wet scrubbing using a (
limestone) slurry produces
calcium sulfite () and may be expressed in the simplified dry form as: : Wet scrubbing can be conducted with a (
hydrated lime) and : : (M = Ca, Mg) To partially offset the cost of the FGD installation, some designs, particularly dry sorbent injection systems, further oxidize the (calcium sulfite) to produce marketable (
gypsum) that can be of high enough quality to use in
wallboard and other products. The process by which this synthetic gypsum is created is also known as forced oxidation: :2 A natural alkaline usable to absorb is seawater. The is absorbed in the water, and when oxygen is added reacts to form sulfate ions and free . The surplus of is offset by the carbonates in seawater pushing the carbonate equilibrium to release gas: : : In industry
caustic soda () is often used to scrub , producing
sodium sulfite: :2
Types of wet scrubbers used in FGD To promote maximum
gas–liquid surface area and residence time, a number of wet scrubber designs have been used, including spray towers, venturis, plate towers, and mobile
packed beds. Because of scale buildup, plugging, or erosion, which affect FGD dependability and absorber efficiency, the trend is to use simple scrubbers such as spray towers instead of more complicated ones. The configuration of the tower may be vertical or horizontal, and flue gas can flow concurrently, countercurrently, or crosscurrently with respect to the liquid. The chief drawback of spray towers is that they require a higher liquid-to-gas ratio requirement for equivalent removal than other absorber designs. FGD scrubbers produce a scaling wastewater that requires treatment to meet U.S. federal discharge regulations. However, technological advancements in
ion-exchange membranes and
electrodialysis systems has enabled high-efficiency treatment of FGD wastewater to meet EPA discharge limits. The treatment approach is similar for other highly scaling industrial wastewaters.
Venturi-rod scrubbers A
venturi scrubber is a converging/diverging section of duct. The converging section accelerates the gas stream to high velocity. When the liquid stream is injected at the throat, which is the point of maximum velocity, the turbulence caused by the high gas velocity atomizes the liquid into small droplets, which creates the surface area necessary for mass transfer to take place. The higher the pressure drop in the venturi, the smaller the droplets and the higher the surface area. The penalty is in power consumption. For simultaneous removal of and fly ash, venturi scrubbers can be used. In fact, many of the industrial sodium-based throwaway systems are venturi scrubbers originally designed to remove particulate matter. These units were slightly modified to inject a sodium-based scrubbing liquor. Although removal of both particles and in one vessel can be economic, the problems of high pressure drops and finding a scrubbing medium to remove heavy loadings of fly ash must be considered. However, in cases where the particle concentration is low, such as from oil-fired units, it can be more effective to remove particulate and simultaneously.
Packed bed scrubbers A packed scrubber consists of a tower with packing material inside. This packing material can be in the shape of saddles, rings, or some highly specialized shapes designed to maximize the contact area between the dirty gas and liquid. Packed towers typically operate at much lower pressure drops than venturi scrubbers and are therefore cheaper to operate. They also typically offer higher removal efficiency. The drawback is that they have a greater tendency to plug up if particles are present in excess in the exhaust air stream.
Spray towers A
spray tower is the simplest type of scrubber. It consists of a tower with spray nozzles, which generate the droplets for surface contact.
Spray towers are typically used when circulating a slurry (see below). The high speed of a venturi would cause erosion problems, while a packed tower would plug up if it tried to circulate a slurry. Counter-current packed towers are infrequently used because they have a tendency to become plugged by collected particles or to scale when
lime or
limestone scrubbing slurries are used.
Scrubbing reagent As explained above, alkaline sorbents are used for scrubbing flue gases to remove . Depending on the application, the two most important are
lime and
sodium hydroxide (also known as
caustic soda). Lime is typically used on large coal- or oil-fired boilers as found in power plants, as it is very much less expensive than caustic soda. The problem is that it results in a slurry being circulated through the scrubber instead of a solution. This makes it harder on the equipment. A spray tower is typically used for this application. The use of lime results in a slurry of calcium sulfite () that must be disposed of. Calcium sulfite can be oxidized to produce by-product gypsum () which is marketable for use in the building products industry. Caustic soda is limited to smaller combustion units because it is more expensive than lime, but it has the advantage that it forms a solution rather than a slurry. This makes it easier to operate. It produces a "
spent caustic" solution of
sodium sulfite/bisulfite (depending on the pH), or sodium sulfate that must be disposed of. This is not a problem in a
kraft pulp mill for example, where this can be a source of makeup chemicals to the recovery cycle.
Scrubbing with sodium sulfite solution It is possible to scrub
sulfur dioxide by using a cold solution of
sodium sulfite; this forms a sodium hydrogen sulfite solution. By heating this solution it is possible to reverse the reaction to form sulfur dioxide and the sodium sulfite solution. Since the sodium sulfite solution is not consumed, it is called a regenerative treatment. The application of this reaction is also known as the
Wellman–Lord process. In some ways this can be thought of as being similar to the reversible
liquid–liquid extraction of an
inert gas such as
xenon or
radon (or some other solute which does not undergo a chemical change during the extraction) from water to another phase. While a chemical change does occur during the extraction of the sulfur dioxide from the gas mixture, it is the case that the extraction equilibrium is shifted by changing the temperature rather than by the use of a chemical reagent.
Gas-phase oxidation followed by reaction with ammonia A new, emerging flue gas desulfurization technology has been described by the
IAEA. It is a
radiation technology where an intense beam of
electrons is fired into the flue gas at the same time as
ammonia is added to the gas. The Chendu power plant in China started up such a flue gas desulfurization unit on a 100 MW scale in 1998. The Pomorzany power plant in Poland also started up a similar sized unit in 2003 and that plant removes both sulfur and nitrogen oxides. Both plants are reported to be operating successfully. However, the accelerator design principles and manufacturing quality need further improvement for continuous operation in industrial conditions. No
radioactivity is required or created in the process. The electron beam is generated by a device similar to the
electron gun in a TV set. This device is called an accelerator. This is an example of a radiation chemistry process ==Facts and statistics==