Encyclopedia of Renewable Energy. James G. Speight. Читать онлайн. Newlib. NEWLIB.NET

Автор: James G. Speight
Издательство: John Wiley & Sons Limited
Серия:
Жанр произведения: Физика
Год издания: 0
isbn: 9781119364092
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can be derived as a function of the AEBP.

      Typically, as the mid-AEBP increases, the sulfur and nitrogen concentrations of the fraction generally also increase. Also, the highest concentrations of both sulfur and nitrogen appear in the non-distillable fractions. This behavior follows the heteroatom behavior observed for refinery distillation cuts. Thus, the higher the boiling range of the fraction, the higher the heteroatom concentration. This also establishes that the heteroatom concentration continues to increase as the volatility of the compounds decreases, which was not known previously for the 540°C+ (1000°F+) residuum.

      Atomic Energy

      Atomic energy is the source of nuclear power which uses sustained nuclear fission to generate heat and electricity. It is also the source of the explosive force of an atomic bomb. The energy originates from the splitting of uranium atoms (nuclear fission) which generates heat to produce steam, which is used by a turbine generator to generate electricity. Because nuclear power plants do not burn fuel, they do not produce greenhouse gas emissions but, caution is advised, and although the risk of accidents in nuclear power plants is low, the consequences of an accident can be drastic and highly detrimental to the surrounding flora and fauna (including human life).

      See also: Nuclear Energy, Nuclear Fission, Nuclear Fusion.

      Attapulgus Clay

      Attapulgus clay (attapulgite or palygorskite) is a magnesium aluminum phyllosilicate [(Mg.Al)2Si4O10.4H2O) which occurs in a type of clay soil common to the Southeastern United States. It is one of the types of fuller’s earth.

      The name attapulgite is derived from the U.S. town of Attapulgus, Georgia, in the extreme southwest corner of the state, where the mineral is abundant. It is surface-mined in the area, dry-ground and air-separated into precise particle sizes, and transported in covered hopper cars via the railroad, and is also shipped in 50-lb bags and bulk bags by truck. The name palygorskite is given after the place in the Ural Mountains where it was discovered.

      Attapulgite clays are swellable clays like bentonite, although more acicular (or needle like). Attapulgite, unlike bentonite, will swell in salt water and is used in special salt water drilling mud for off shore oil drilling. Like many clays, they can be considered as charged particles with zones of positive and negative charges. Standard attapulgite clays are agglomerated bundles of clay particles between 20 and 100 µm long and below 1 µm in diameter. Most grades contain up to 25% non-attapulgite material in the form of mineral carbonates and other inclusions. The advantage of attapulgites is that their performance is not temperature sensitive and they have lower water demand. They must have free ions in an aqueous system to work.

      See also: Clay Minerals, Clay Treating Process.

      Attrition Catalyst

      Typically, a relatively inexpensive catalyst that is designed to remove impurities and unwanted by-products from gas streams which, at the same time, is sacrificed. For example, alumina (Al2O3) guard beds serve as protectors by the act of attrition and may be referred to as an attrition reactor containing an attrition catalyst may be placed ahead of the molecular sieves to remove the sulfur compounds. Downflow reactors are commonly used for adsorption processes, with an upward flow regeneration of the adsorbent and cooling using gas flow in the same direction as adsorption flow.

      See also: Guard Bed, Guard Bed Reactor.

      Azeotrope

      Two main types of azeotropes exist, i.e., the homogeneous azeotrope, where a single liquid phase is in the equilibrium with a vapor phase; and the heterogeneous azeotropes, where the overall liquid composition which form two liquid phases, is identical to the vapor composition. Most methods of distilling azeotropes and low relative volatility mixtures rely on the addition of specially chosen chemicals to facilitate the separation.

      A simple distillation residue curve is a means by which the changes in the composition of the liquid residue curves on the pot changes over time. Residue curve map is a collection of the liquid residue curves originating from different initial compositions. Residue curve maps contain the same information as phase diagrams, but represent this information in a way that is more useful for understanding how to synthesize a distillation sequence to separate a mixture.

      All of the residue curves originate at the light (lowest boiling) pure component in a region, move toward the intermediate boiling component, and end at the heavy (highest boiling) pure component in the same region. The lowest temperature nodes are termed as unstable nodes, as all trajectories leave from them, while the highest temperature points in the region are termed stable nodes, as all trajectories ultimately reach them. The point that the trajectories approach from one direction and end in a different direction (as always is the point of intermediate boiling component) is termed saddle point. Residue curves that divide the composition space into different distillation regions are called distillation boundaries.

      The separation of components of similar volatility may become economical if an entrainer can be found that effectively changes the relative volatility. It is also desirable that the entrainer be reasonably cheap, stable, non-toxic, and readily recoverable from the components. In practice, it is probably this last criterion that severely limits the application of extractive and azeotropic distillation. The majority of successful processes, in fact, are those in which the entrainer and one of the components separate into two liquid phases on cooling if direct recovery by distillation is not feasible.

      A further restriction in the selection of an azeotropic entrainer is that the boiling point of the entrainer be in the range 10 to 40°C (18 to 72°F) below that of the components. Thus, although the entrainer is more volatile than the components and distills off in the overhead product, it is present in a sufficiently high concentration in the rectification