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Fundamental Studies Concerning Calcium-Based Sorbents
Abstract
Sorbent preparation techniques used today have generally been adapted from techniques traditionally used by the lime industry. Traditional “dry” hydration and slaking processes have been optimized to produce materials intended for use in the building industry. These preparation techniques should be examined with an eye to optimization of properties important to the SO2 capture process.
The study of calcium-based sorbents for sulfur dioxide capture is complicated by two factors: (1) little is known about the chemical mechanisms by which the “standard” sorbent preparation and enhancement techniques work, and (2) a sorbent preparation technique that produces a calcium-based sorbent that enjoys enhanced calcium utilization in one regime of operation [flame zone (>2400°F), in-furnace (1600–2400°F), economizer (800–1100°F), after air preheater (<350°F)] may not produce a sorbent that enjoys enhanced calcium utilization in the other reaction zones. Again, an in-depth understanding of the mechanism of sorbent enhancement is necessary if a systematic approach to sorbent development is to be used.
The long-term goals of the experimental program that resulted in this report were (1) defining the effects of slaking conditions on the properties of calcium-based sorbents, (2) determining how the parent limestone properties and preparation techniques interact to define the SO2 capture properties of calcium-based sorbents, and (3) elucidating the mechanism(s) relating to the activity of various dry sorbent additives.
This chapter documents (1) the collection, production, and characterization of a series of limestone/hydrated lime/quicklime samples representing a range of Ohio limestone products, (2) an investigation of the importance of lime solubility enhancement in the evolution of surface area during the slaking process, and (3) a model/paper study of the effects of chemical additives on the performance in spray drying and in-duct injection processes.
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The report gives results of a characterization of the current state of knowledge regarding SOâ capture by dry calcitic sorbent injection. In this project, the experimental data on dry sorbent injection are compiled and critically compared. Sulfation and activation models are developed and used to identify sorbent properties and furnace-environment parameters likely to be of importance. The results of the examination of data and the model evaluation indicated areas where original experimental work could be applied to resolve key issues. The experimental portion of the program developed information on injection temperature, quench rate, and sorbent properties. These results are used to define the overall optimum injection condition for a variety of furnace configurations.
Gilbert Commonwealth, Southern Research Institute and the American Electric Power Service Corporation have embarked on a program to convert DOE`s Duct Injection Test Facility located at the Muskingum River Power Plant of Ohio Power Company to test alternate duct injection technologies. The technologies to be tested include slurry sorbent injection of hydrated lime using dual fluid nozzles, or a rotary atomizer and pneumatic injection of hydrated lime, with flue gas humidification before or after sorbent injection. The literature review and analysis contained in this report is a part of the preparatory effort for the test program.
Experimental data on sulfation rates of CaO particles derived from CaCO3 are compared to those derived from Ca(OH)2 using a product layer diffusion control model differing only in the shape of the CaO grain. Both the model and the experimental data indicate slightly higher reactivity for the Ca(OH)2-derived oxide due to the observed difference in grain shape. This effect is considered as a contributor to the greater performance of Ca(OH)2 in pilot-scale SO2 removal studies.
Changes in the pore structure of calcium oxide sorbents derived from calcium carbonate (c-CaO) and calcium hydroxide (h-CaO) reacting with sulfur dioxide are determined. Results show that the pore shape of c-CaO approximates a cylinder while that of h-CaO appears to be slit- or platelike. The pore volume of c-CaO is located in much smaller pores than that of h-CaO when compared on the basis of an equivalent pore shape model. The effect of sintering was to reduce surface area through coalescence of smaller pores, while only minor effects were observed upon pore volume and conversion from calcium oxide to calcium sulfate. Both sorbents expand to allow greater reaction than is possible given the initial porosity and formation of a larger volume product. The h-CaO reacts to higher levels of conversion than the c-CaO because the pore shape of the h-CaO allows for greater particle expansion and, therefore, reaction beyond the limits of the initial porosity.
The rate of reaction of calcined limestone with SO2 and O2 was measured at conditions that eliminate all resistances not associated with the CaO grain surface. Reactivity increased with the square of the BET surface area when grain size was varied as an experimental parameter. The observed effects of surface area and temperature account for the SO2 capture reported for boiler tests of the limestone injection process.
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