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Homogeneous azeotropes

Exploitation of Homogeneous Azeotropes Homogeneous azeotropic distillation refers to a flowsheet structure in which azeotrope formation is exploited or avoided in order to accomplish the desired separation in one or more distillation columns. The azeotropes in the system either do not exhibit two-hquid-phase behavior or the hquid-phase behavior is not or cannot be exploited in the separation sequence. The structure of a particular sequence will depend on the geometry of the residue curve map or distillation region diagram for the feed mixture-entrainer system. Two approaches are possible ... [Pg.1307]

E]mloiting Homogeneous Azeotropes Homogeneous azeotropic distilMion refers to allow sheet structure in which azeotrope formation is ejq)loited or avoided in order to accomplish the desired separation in one or more distillation columns. Either the azeotropes in the system... [Pg.81]

The relative volatiHty of most mixtures changes with temperature, pressure, and composition. The larger the value of the easier it is to separate component / from componentj. From equation 2, at a ( component, ie, biaary, ternary, etc, homogeneous azeotrope, for all c components ia the... [Pg.180]

The first step in the synthesis of a homogeneous azeotropic distillation sequence is to determine the separation objective. Eor example, sometimes it is deskable to recover all of the constituents in the mixture as pure components, other times it is sufficient to recover only some of the pure components as products. In other cases an azeotrope may be the desked product. Not every objective is attainable and those that are feasible may requke different distillation sequences. [Pg.182]

As a starting point for identifying candidate solvents, all compounds having boiling points below that of any component in the mixture to be separated should be eliminated. This is necessary to yield the correct residue curve map for extractive distillation, but this process implicitly rules out other forms of homogeneous azeotropic distillation. In fact, compounds which boil as much as 50°C or more above the mixture have been recommended (68) in order to minimize the likelihood of azeotrope formation. On the other hand, the solvent should not bod so high that excessive temperatures are required in the solvent recovery column. [Pg.189]

Fig. 13. Schematic isobatic phase diagrams for binary azeotropic mixtures (az). (a) Homogeneous azeotrope (b) heterogeneous azeotrope. Fig. 13. Schematic isobatic phase diagrams for binary azeotropic mixtures (az). (a) Homogeneous azeotrope (b) heterogeneous azeotrope.
Fig. 15. Isobaric vapor—liquid—liquid (VLLE) phase diagrams for the ethanol—water—benzene system at 101.3 kPa (D-D) representHquid—Hquid tie-lines (A—A), the vapor line I, homogeneous azeotropes , heterogeneous azeotropes Horsley s azeotropes, (a) Calculated, where A is the end poiat of the vapor line and the numbers correspond to boiling temperatures ia °C of 1, 70.50 2, 68.55 3, 67.46 4, 66.88 5, 66.59 6, 66.46 7, 66.47, and 8, the critical poiat, 66.48. (b) Experimental, where A is the critical poiat at 64.90°C and the numbers correspond to boiling temperatures ia °C of 1, 67 2, 65.5 3, 65.0 ... Fig. 15. Isobaric vapor—liquid—liquid (VLLE) phase diagrams for the ethanol—water—benzene system at 101.3 kPa (D-D) representHquid—Hquid tie-lines (A—A), the vapor line I, homogeneous azeotropes , heterogeneous azeotropes Horsley s azeotropes, (a) Calculated, where A is the end poiat of the vapor line and the numbers correspond to boiling temperatures ia °C of 1, 70.50 2, 68.55 3, 67.46 4, 66.88 5, 66.59 6, 66.46 7, 66.47, and 8, the critical poiat, 66.48. (b) Experimental, where A is the critical poiat at 64.90°C and the numbers correspond to boiling temperatures ia °C of 1, 67 2, 65.5 3, 65.0 ...
Fig. 18. Separation of ethanol from an ethanol—water—benzene mixture using benzene as the entrainer. (a) Schematic representation of the azeo-column (b) material balance lines where I denotes the homogeneous and the heterogeneous azeotropes D, the end points of the Hquid tie-line and A, the overhead vapor leaving the top of the column. The distillate regions, I, II, and III, and the boundaries are marked. Other terms are defined in text. Fig. 18. Separation of ethanol from an ethanol—water—benzene mixture using benzene as the entrainer. (a) Schematic representation of the azeo-column (b) material balance lines where I denotes the homogeneous and the heterogeneous azeotropes D, the end points of the Hquid tie-line and A, the overhead vapor leaving the top of the column. The distillate regions, I, II, and III, and the boundaries are marked. Other terms are defined in text.
Podebush Sequence forPthanol—Water Separation. When ethyl acetate is used as the entrainer to break the ethanol—water azeotrope the residue curve map is similar to the one shown in Figure 21d, ie, the ternary azeotrope is homogeneous. Otherwise the map is the same as for ethanol—water—benzene. In such... [Pg.198]

An example of heterogeneous-azeotrope formation is shown in Fig. 13-13 for the water-normal butanol system at 101.3 kPa. At liquid compositions between 0 and 3 mole percent butanol and between 40 and 100 mole percent butanol, the liquid phase is homogeneous. Phase sphtting into two separate liquid phases (one with 3 mole percent butanol and the other with 40 mole percent butanol) occurs for any overall hquid composition between 3 and 40 mole percent butanol. A miuimum-boihug heterogeneous azeotrope occurs at 92°C (198°F) when the vapor composition and the over l composition of the two liquid phases are 75 mole percent butanol. [Pg.1248]

Three types of binary equilibrium cui ves are shown in Fig. 13-27. The y-x diagram is almost always plotted for the component that is the more volatile (denoted by the subscript 1) in the region where distillation is to take place. Cui ve A shows the most usual case, in which component 1 remains more volatile over the entire composition range. Cui ve B is typical of many systems (ethanol-water, for example) in which the component that is more volatile at lowvalues of X becomes less volatile than the other component at high values of X. The vapor and liquid compositions are identical for the homogeneous azeotrope where cui ve B crosses the 45° diagonal. A heterogeneous azeotrope is formed with two liquid phases by cui ve C,... [Pg.1265]

FIG. 13-27 Typical binary eqiiilihriiim curves. Curve A, system with normal volatility. Curve B, system with homogeneous azeotrope (one liquid phase). Curve C, system with heterogeneous azeotrope (two liquid phases in eqiiilih-riiim with one vapor phase). [Pg.1265]

FIG. 13-57 (Continued) Schematic isoharic-phase diagrams for binary azeotropic mixtures, (b) Homogeneous maximum-boiling azeotrope. [Pg.1293]

As mentioned previously, ternaiy mixtures can be represented by 125 different residue curve maps or distillation region diagrams. However, feasible distillation sequences using the first approach can be developed for breaking homogeneous binaiy azeotropes by the addition of a third component only for those more restricted systems that do not have a distillation boundaiy connected to the azeotrope and for which one of the original components is a node. For example, from... [Pg.1307]

FIG. 13-64 Feasible distillation region diagrams for breaking homogeneous binary azeotrope A-B, a) Low-boiling entranoes. [Pg.1308]

Exploitation of Pressure Sensitivity The breaking of homogeneous azeotropes that are part of a distiUation boundary (that is, into produc ts in different distillation regions) requires that the boundaiy... [Pg.1310]

See other pages where Homogeneous azeotropes is mentioned: [Pg.195]    [Pg.400]    [Pg.159]    [Pg.179]    [Pg.180]    [Pg.180]    [Pg.182]    [Pg.182]    [Pg.182]    [Pg.184]    [Pg.185]    [Pg.190]    [Pg.190]    [Pg.191]    [Pg.193]    [Pg.194]    [Pg.194]    [Pg.195]    [Pg.197]    [Pg.1240]    [Pg.1248]    [Pg.1293]    [Pg.1294]    [Pg.1307]    [Pg.1308]    [Pg.1308]    [Pg.1309]    [Pg.1310]   
See also in sourсe #XX -- [ Pg.41 ]

See also in sourсe #XX -- [ Pg.384 , Pg.400 , Pg.411 , Pg.537 ]



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