Process for high purity hexane and production thereof

Abstract

The invention relates to the production of High purity n-hexane from low value stream such as raffinate from benzene extraction unit in crude oil refineries employing extractive distillation. The present invention further related to an extractive distillation employing an organic solvent having comparable or same Hansen dispersive force parameter (.sub.d) of that of the key component of to be separated through extractive distillation. The present invention is useful for separating and isolating pure cyclohexane, pure methylcyclopentane and pure iso-heptane along with the pure n-hexane.

Claims

1. A process for producing n-hexane, said process comprising: (a) subjecting a benzene saturated hydrocarbon stream to fractional separation at a temperature in range of 65 C. to 100 C. to split the benzene saturated hydrocarbon stream into a top stream and a bottom stream, wherein the bottom stream comprises a mixture of cyclohexane and iso-heptane and the top stream comprises a mixture of methylcyclopentane (MCP) and n-hexane; (b) subjecting the top stream of step (a) to extractive distillation to obtain n-hexane and methylcyclopentane by using an organic solvent; and (c) separating n-hexane.

2. The process as claimed in claim 1, wherein the extractive distillation of said top stream of step (a) further comprises steps of: (a) subjecting a feed containing the top steam comprising methylcyclopentane and n-hexane to the extractive distillation; (b) separating a n-hexane rich stream and a methylcyclopentane rich stream from the feed of step (a) by addition of an organic solvent wherein the solvent to the feed ratio is 3% vol/vol; (c) isolating the n-hexane rich stream and the methylcyclopentane rich stream containing organic solvent separately; (d) partially condensing the n-hexane rich stream of step (c) to obtain a condensed stream comprising n-hexane; and (e) separating the organic solvent from the methyl cyclopentane rich stream of step (c) to obtain methylcyclopentane.

3. The process as claimed in claim 2, wherein a portion of the condensed stream of n-hexane obtained from step (d) is returned back as a reflux for the extractive distillation.

4. The process as claimed in claim 2, wherein the organic solvent obtained from step (e) is recycled back to step (b) for separation of the n-hexane rich stream and methylcyclopentane rich stream from the feed.

5. The process as claimed in claim 2, wherein the organic solvent is selected from monoethylene glycol (MEG), triethylene glycol (TEG), N-methyl pyrrolidone (NMP), sulfolane and dimethyl sulfoxide (DMSO).

6. The process as claimed in claim 1, wherein the extractive distillation of the bottom stream of step (b) comprises steps of: (a) subjecting a feed containing the bottom stream comprising a mixture of cyclohexane and iso-heptane to extractive distillation; (b) separating an iso-heptane rich stream and a cyclohexane rich stream from the feed of step (a) by addition of an organic solvent wherein the solvent to the feed ratio is 3% vol/vol; (c) isolating the iso-heptane rich stream and the cyclohexane rich stream containing organic solvent separately; (d) partially condensing the iso-heptane rich stream of step (c) to obtain isoheptane; and (e) separating the organic solvent from the cyclohexane rich stream of step (c) to obtain cyclohexane.

7. The process as claimed in claim 6, wherein a portion of condensed stream of iso-heptane obtained from step (d) is returned back as a reflux for the extractive distillation.

8. The process as claimed in claim 6, wherein the organic solvent is selected from monoethylene glycol (MEG), triethylene glycol (TEG), N-methyl pyrrolidone (NMP), sulfolane and dimethyl sulfoxide (DMSO).

9. The process as claimed in claim 6, wherein the organic solvent obtained from step (e) is recycled back to step (b) for separation of the iso-heptane rich stream and cyclohexane rich stream from the feed.

10. The process as claimed in claim 1, wherein the process is further used for isolation of methylcyclopentane, iso-heptane and cyclohexane along with the n-hexane.

Description

DRAWINGS

(1) FIG. 1 is a diagrammatic representation of apparatus for producing pure n-hexane, pure methylcyclopentane, pure cyclohexane and pure iso-heptane.

DESCRIPTION OF THE INVENTION

(2) While the invention is susceptible to various modifications and/or alternative processes and/or compositions, specific embodiment thereof has been shown by way of example in the drawings and tables and will be described in detail below. It should be understood, however that it is not intended to limit the invention to the particular processes and/or compositions disclosed, but on the contrary, the invention is to cover all modifications, equivalents, and alternative falling within the spirit and the scope of the invention as defined by the appended claims.

(3) The tables have been represented where appropriate by conventional representations showing only those specific details that are pertinent to understanding the embodiments of the present invention so as not to obscure the disclosure with details that will be readily apparent to those of ordinary skill in the art having benefit of the description herein.

(4) The following description is of exemplary embodiments only and is not intended to limit the scope, applicability or configuration of the invention in any way. Rather, the following description provides a convenient illustration for implementing exemplary embodiments of the invention. Various changes to the described embodiments may be made in the function and arrangement of the elements described without departing from the scope of the invention.

(5) In accordance with this invention, in a process for the simultaneous production of cyclohexane, methylcyclopentane and high purity hexane from C.sub.6 refinery stream containing 6-7 carbon atoms by employing series of processes including fractional distillation, and extractive distillation using a solvent (also referred to as extractant or entrainer) in extractive distillation unit wherein said solvent is at least one saturated alcohol selected from the group consisting of alkanols and cycloalkanols, wherein said alkanols are selected from the group comprising of C5 to C9 carbon atoms.

(6) Accordingly, the main embodiment of the present invention relates to a process of preparing high purity n-hexane by extractive distillation of a hydrocarbon feedstock, wherein the extractive distillation is carried out using an organic solvent having comparable to same Hansen dispersive force parameter (.sub.d) to hexane.

(7) In other embodiment the hydrocarbon feedstock is a light naphtha feedstock comprising C.sub.6 raffinate stream of paraffins and cycloparaffins.

(8) In a preferred embodiment the hydrocarbon feedstock is mixture of predominately cyclohexane, methylcyclopentane, n-hexane and iso-heptanes.

(9) In another embodiment, the organic solvent is selected from the group comprising of C5-C9 alkanols and C5-C9 cycloalkanols.

(10) In another preferred embodiment, the organic solvent is selected from monoethylene glycol (MEG), triethylene glycol (TEG), N-methyl pyrrolidone (NMP), Sulfolane and dimethyl sulfoxide (DMSO). In most preferred embodiment, the organic solvent is selected from monoethylene glycol (MEG) and triethylene glycol (TEG) with matching Hansen solubility parameter and more preferably the matching dispersive force.

(11) Hansen Solubility Parameter:

(12) Solvents suitable for extractive distillation of compounds of interest were selected based on Hansen solubility parameter in the present invention. When a compound is dissolved in a solvent, intermolecular interactions develop between molecules, in order to achieve good solubility, intermolecular interaction force between the solute and solvent should be identical or at least comparable. When the non-polar molecules dissolves in the polar solvent, stronger intermolecular force develop than those in non-polar solutes. The solubility characteristics of the solvent and solute are based on three parameters which are known as the Hansen Solubility Parameters. The Hansen Solubility Parameters are the factors that determine which set of molecules will interact strongly with other molecules. The stronger the interaction, the more soluble those compounds are expected to be. Hence it is an effective method at determining ideal solvents for given solutions of feed. These three forces are:

(13) 1) Energy from dispersion force between molecules (.sub.d)

(14) 2) Energy from dipolar inter-molecular forces between molecules (.sub.p)

(15) 3) Energy from Hydrogen-bonding between molecules (.sub.h).

(16) In Table-1, only cyclohexane and MCP have equal dispersion force (8.2 & 7.7 respectively) as that of solvents, MEG and TEG (8.3 & 7.8 respectively) which is a dominant force for measuring/ensuring good solubility compared to dipolar intermolecular force and hydrogen bonding. The other solvent like NMP and sulfolane do not give the required separation for the High purity hexane because they have higher dispersion force than TEG.

(17) TABLE-US-00001 TABLE 1 dispersion dipolar inter- Hydrogen- Substance force (.sub.d) molecular force (.sub.p) bonding (.sub.p) MEG 8.3 5.4 12.7 TEG 7.8 6.1 9.1 NMP 8.8 6.0 3.5 SULFOLANE 9 7.4 5.3 DMSO 9 8 5 Cyclohexane 8.2 0.0 0.1 Methylcyclopentane 7.7 1.7 0.0 Hexane 7.3 0.0 0.0 2,4-Dimethylpentane 7 0 0

(18) In another preferred embodiment, solvent preferred based on the matching Hansen dispersive force enhances separation factor.

(19) In another preferred embodiment, the enhanced separation factor improves purity of preferred components namely cyclohexane as well as methylcyclopentane and thus reduces separation stages.

(20) The present invention is a process for producing high purity hexane as well as cyclohexane and methylcyclopentane from light naphtha feedstock. The feed of C.sub.6 raffinate stream contains paraffin and cycloparaffins. Benzene saturated hydrocarbon stream is fed to fractional distillation to separate the mixture of cyclohexane and heptanes at the bottom of the column and mixture of methylcyclopentane and n-hexane at the top of the column. Then the both streams processes through extractive distillation separately. In an extractive distillation column, solvent is added which separates the components by changing the relative volatilities of the components of the mixture and effective separation by distillation becomes possible. The solvent for extractive distillation is chosen on the basis of solubility and comparable Hansen dispersive force as that of component to be separated to cause great differences between the relative volatilities of the components in a mixture and ease the separation with fewer distillation stages, lower amount of reflux and higher product purity.

(21) Accordingly, in another preferred embodiment, the present invention provides a process for producing pure n-hexane, said process comprising: (a) subjecting a benzene saturated hydrocarbon stream to fractional separation at a temperature in range of 65 C. to 100 C. to split the benzene saturated hydrocarbon stream into a bottom stream comprising a mixture of cyclohexane and iso-heptane and a top stream comprising a mixture of methylcyclopentane (MCP) and n-hexane; (b) subjecting the top stream of step (a) to extractive distillation to obtain n-hexane and methylcyclopentane by using an organic solvent; and (c) separating pure n-hexane.

(22) In other embodiment, after benzene saturation, the hydrocarbon feed (i.e. saturated light naphtha feedstock) contains predominantly cyclohexane, methylcyclopentane and paraffins like n-hexane and iso-heptanes with benzene less <100 ppm. The minimum boiling point of feed should not be less than 65 and should not be more than 100.

(23) In another embodiment, the extractive distillation of top stream further comprises of: (a) subjecting a feed containing top stream comprising methylcyclopentane and n-hexane to the extractive distillation; (b) separating n-hexane rich stream and methylcyclopentane rich stream from the feed of step (a) by addition of an organic solvent wherein the solvent to the feed ratio is 3% vol/vol; (c) isolating the n-hexane rich stream and a methylcyclopentane rich stream containing organic solvent separately; (d) partially condensing the n-hexane rich stream of step (c) to obtain pure n-hexane; and (e) separating the organic solvent from the methylcyclopentane rich stream of step (c) to obtain pure methylcyclopentane.

(24) In one another embodiment, a portion of condensed stream of n-hexane obtained from step (d) is returned back as a reflux for the extractive distillation.

(25) In one another embodiment, the organic solvent obtained from step (e) is recycled back to step (b) for separation of the n-hexane rich stream and methylcyclopentane rich stream from the feed.

(26) In a preferred embodiment, the organic solvent is selected from monoethylene glycol (MEG), triethylene glycol (N-methyl pyrrolidone (NMP), sulfolane and dimethyl sulfoxide (DMSO) and most preferably from MEG and TEG.

(27) In another embodiment, the extractive distillation of the bottom stream of step (b) comprises steps of: (a) subjecting a feed containing bottom stream comprising a mixture of cyclohexane and iso-heptane to extractive distillation; (b) separating iso-heptane rich stream and cyclohexane rich stream from the feed of step (a) by addition of an organic solvent wherein the solvent to the feed ratio is 3% vol/vol; (c) isolating the iso-heptane rich stream and a cyclohexane rich stream containing organic solvent separately; (d) partially condensing the iso-heptane rich stream of step (c) to obtain pure iso-heptane; and (e) separating the organic solvent from the cyclohexane rich stream of step (c) to obtain pure cyclohexane.

(28) In further embodiment, a portion of condensed stream of iso-heptane obtained from step (d) is returned back as a reflux for the extractive distillation.

(29) Also, the organic solvent obtained from step (e) is recycled back to step (b) for separation of the iso-heptane rich stream and cyclohexane rich stream from the feed.

(30) The feed mixture comprising C.sub.6 raffinate hydrocarbons and para-xylene raffinate is benzene saturated where benzene is converted into cyclohexane. The benzene saturated hydrocarbon stream thus obtained is sent to fractionators [4] through conduit [1] for splitting into two streams to cyclohexane rich bottom stream through conduit [6] and MCP rich stream through conduit [5] respectively. The lighter fractions [2] (having hydrocarbon with carbon atoms less than C.sub.6) and the heavier fractions [3] (having hydrocarbon with carbon atoms more than C.sub.6) are separated from the fractionator [4].

(31) Extractive Distillation:

(32) The MCP rich stream containing n-hexane conduit [5] is then fed to extractive distillation column [8] where the Solvent from solvent storage [29] is introduced to extractive distillation column [8] through conduit [10], and an overhead stream enriched in High purity hexane is withdrawn from an upper portion of distillation column [8] through conduit [11]. This overhead stream can be partially condensed, with a portion thereof being returned to the fractionation zone as reflux. The overhead stream passing through conduit [11] is condensed in condenser [31] to yield a condensed overhead stream. A portion of the condensed overhead stream can be returned to distillation column [8] as reflux through conduit [17], while the remainder of the condensed overhead stream is yielded as a High purity hexane through conduit [21].

(33) A bottoms stream of extractive distillation column [8] rich with MCP is withdrawn from a lower portion of the extractive distillation column [8] through conduit [13]. A portion of the fluids withdrawn from the bottom of extractive distillation column [8] may be heated in reboiler [32] and then passed back to a lower portion of extractive distillation column [8] through conduit [19]. The feed mixture introduced into extractive distillation column [8] will be fractionated to yield an overhead stream which is enriched in High purity hexane and a bottoms stream predominantly comprising the MCP and the solvent.

(34) The bottoms stream passing through conduit [13] is passed to distillation column [15]. Differences in the boiling point and adjustment of the temperature in the distillation column, the bottoms stream passing through conduit [13] can be easily fractionated into solvent stream [33]. An overhead stream predominantly comprising MCP is withdrawn from an upper portion of distillation column [15] through conduit [23]. This overhead stream can be at least partially condensed in condenser [34]. A portion of the overhead stream withdrawn from condenser [34] can be returned through conduit [25] as reflux for MCP through conduit [25].

(35) A bottoms stream mainly comprising the solvent is withdrawn from a lower portion of distillation column [15] through conduit [33]. A portion of this bottoms stream is preferably routed back to solvent stream [29] and then recycled to extractive distillation column [8], while another portion of the bottoms stream is heated in a reboiler [35] and returned to the lower portion of column [15]. Solvent lost during processing is made up by a makeup stream passing through conduit [33] and solvent stream [29].

(36) The cyclohexane rich stream conduit [6] is then fed to extractive distillation column [7] where the Solvent from solvent storage [30] is introduced to extractive distillation column [7] through conduit [9], and an overhead stream enriched in iso-heptanes is withdrawn from an upper portion of distillation column [7] through conduit [12]. This overhead stream can be partially, with a portion thereof being returned to the fractionation zone as reflux. The overhead stream passing through conduit [12] is condensed in condenser [36] to yield a condensed overhead stream. A portion of the condensed overhead stream can be returned to distillation column [7] as reflux through conduit [18], while the remainder of the condensed overhead stream is yielded as a product through conduit [22].

(37) A bottom stream of extractive distillation column [7] rich with cyclohexane is withdrawn from a lower portion of the extractive distillation column [7] through conduit [14]. A portion of the fluids withdrawn from the bottom of distillation column [14] may be heated in reboiler [37] and then passed back to a lower portion of distillation column [7] through conduit [20].

(38) The feed mixture introduced into extractive distillation column [7] will be fractionated to yield an overhead stream which is enriched in High purity hexane and a bottoms stream predominantly comprising the cyclohexane and the solvent.

(39) The bottom stream passing through conduit [14] is passed to distillation column [16]. Differences in the boiling point and adjustment of the temperature in the distillation column, the bottoms stream passing through conduit [14] can be easily fractionated into solvent stream [38]. An overhead stream predominantly comprising cyclohexane is withdrawn from an upper portion of distillation column [16] through conduit [24]. This overhead stream can be at least partially condensed in condenser [39]. A portion of the overhead stream withdrawn from condenser [39] can be returned through conduit [26] as reflux for distillation column [16], with the remainder of the overhead stream being withdrawn as product, i.e., cyclohexane through conduit [26].

(40) A bottom stream predominantly comprising the solvent is withdrawn from a lower portion of distillation column [16] through conduit [38]. A portion of this bottoms stream is preferably routed back to solvent stream [30] and then recycled to extractive distillation column [7], while another portion of the bottoms stream is heated in a reboiler [40] and returned to the lower portion of column [16]. Solvent lost during processing losses can be made up by a makeup stream passing through conduit [38] and solvent stream [30].

(41) Accordingly, in another embodiment, the present invention relates to an apparatus for producing pure n-hexane wherein said apparatus comprising: (a) a fractional distillation unit [4] to split a benzene saturated hydrocarbon stream into a bottom stream comprising cyclohexane and iso-heptane, and a top stream comprising methylcyclopentane (MCP) and n-hexane; (b) an extractive distillation column [8] for fractionating the top stream into an overhead stream rich in n-hexane and a bottom stream comprising methylcyclopentane and organic solvent; (c) a solvent storage [29] for introducing solvent to the extractive distillation column [8]; (d) a condenser [31] for condensing pure n-hexane stream wherein a portion of condensed stream is passed to the extractive distillation column [8] through a conduit [17]; and (e) a conduit [21] for isolating pure n-hexane.

(42) In another embodiment of the present invention, the apparatus of the present invention further comprises of: (a) a distillation column [15] for separating pure methylcyclopentane stream and organic solvent; (b) a condenser [34] for condensing the pure methylcyclopentane stream wherein a portion of condensed methylcyclopentane stream is returned to the distillation column [15] as a reflux through conduit [25] and remaining is isolated through conduit [25]; (c) a conduit [33] for transferring a portion of organic solvent from the distillation column [15] to the solvent storage [29]; and (d) a reboiler [35] for heating a portion of the organic solvent and returning the hot organic solvent to the bottom of the distillation column [15].

(43) In one another embodiment, the apparatus of the present invention further comprises of: (a) an extractive distillation column [7] for fractionating overhead iso-heptane rich stream and a bottom stream comprising cyclohexane and organic solvent; (b) a solvent storage [30] for introducing solvent to the extractive distillation column [7]; (c) a condenser [36] for condensing the overhead iso-heptane stream wherein a portion of condensed stream is returned to the extractive distillation column [7] as a reflux through a conduit [18]; (d) a conduit [22] for isolating pure iso-heptane.

(44) In one another embodiment of the present invention, the apparatus of the present invention further comprises of: (a) a distillation column [16] for fractionating cyclohexane and organic solvent wherein isolating pure cyclohexane stream from top of the distillation column [16] and organic solvent from bottom of the distillation column [16]; (b) a condenser [39] for condensing the pure cyclohexane stream wherein a portion of condensed cyclohexane stream is returned to the distillation column [16] through conduit [26] and remaining is isolated through conduit [26]; (c) a conduit [38] for transferring a portion of organic solvent from the distillation column [16] to the solvent storage [30]; and (d) a reboiler [40] for heating a portion of the organic solvent and returning the hot organic solvent to the bottom of the distillation column [16].

(45) In further embodiment, the process of the present invention optionally comprises of a step wherein a portion of the fluids withdrawn from the bottom of the extractive distillation column [8] may be heated in reboiler [32] and then passed back to a lower portion of extractive distillation column [8] through conduit [19].

Example 1

(46) Experiments were conducted with hydrocarbon feedstock consisting of hexane and methylcyclopentane with MEG as a solvent. The solvent-to feed ratio was 3 vol/vol. The mixture of solvent and feed were heated to a temperature of 75 C. and the vapors were condensed and completely refluxed back to the solvent feed mixture. After 2 hours of distillation and total reflux, samples of both liquid and condensed vapor were collected and analyzed for composition. The results are summarized in the following table.

(47) TABLE-US-00002 Liquid Feed Phase Vapor Phase n-Hexane % 69.1 58.23 72.41 Methylcyclopentane, % 30.9 41.77 27.59

(48) The separation factor in the above example has been found to be 1.88

Example 2

(49) Experiments were conducted with hydrocarbon feedstock consisting of hexane and methyl cyclopentane with TEG as a solvent. The solvent-to feed ratio was 3 vol/vol. The mixture of solvent and feed were heated to a temperature of 75 C. and the vapors were condensed and completely refluxed back to the solvent feed mixture. After 2 hours of distillation and total reflux, samples of both liquid and condensed vapor were collected and analyzed for composition. The results are summarized in the following table.

(50) TABLE-US-00003 Liquid Feed Phase Vapor Phase n-Hexane % 87.91 93.61 86.48 Methylcyclopentane, % 12.09 6.93 13.51

(51) The separation factor in the above example has been found to be 2.29

Example 3

(52) Experiments were conducted with hydrocarbon feedstock consisting of hexane and methyl cyclopentane with NMP as a solvent. The solvent-to feed ratio was 3 vol/vol. The mixture of solvent and feed were heated to a temperature of 75 C. and the vapors were condensed and completely refluxed back to the solvent feed mixture. After 2 hours of distillation and total reflux, samples of both liquid and condensed vapor were collected and analyzed for composition. The results are summarized in the following table.

(53) TABLE-US-00004 Liquid Feed Phase Vapor Phase n-Hexane % 90.51 89.78 97.10 Methylcyclopentane, % 9.49 10.22 2.90

(54) The separation factor in the above example has been found to be 3.81

Example 4

(55) Experiments were conducted with hydrocarbon feedstock consisting of hexane and methyl cyclopentane with Sulfolane as a solvent. The solvent-to feed ratio was 3 vol/vol. The mixture of solvent and feed were heated to a temperature of 75 C. and the vapors were condensed and completely refluxed back to the solvent feed mixture. After 2 hours of distillation and total reflux, samples of both liquid and condensed vapor were collected and analyzed for composition. The results are summarized in the following table:

(56) TABLE-US-00005 Liquid Feed Phase Vapor Phase n-Hexane % 89.56 89.10 91.70 Methylcyclopentane, % 10.44 10.90 8.30

(57) The separation factor in the above example has been found to be 1.35

Example 5

(58) Experiments were conducted with hydrocarbon feedstock consisting of hexane and methyl cyclopentane with DMSO as a solvent. The solvent-to feed ratio was 3 vol/vol. The mixture of solvent and feed were heated to a temperature of 75 C. and the vapors were condensed and completely refluxed back to the solvent feed mixture. After 2 hours of distillation and total reflux, samples of both liquid and condensed vapor were collected and analyzed for composition. The results are summarized in the following table.

(59) TABLE-US-00006 Liquid Feed Phase Vapor Phase n-Hexane % 89.02 89.77 90.05 Methylcyclopentane, % 10.18 10.23 9.95

(60) The separation factor in the above example has been found to be 1.03

Example 6

(61) Experiments were conducted with hydrocarbon feedstock consisting of hexane and methyl cyclopentane with MEG as a solvent. The solvent-to feed ratio was 3 vol/vol. The mixture of solvent and feed were heated to a temperature of 75 C. and the vapors were condensed and completely refluxed back to the solvent feed mixture. After 2 hours of distillation and total reflux, samples of both liquid and condensed vapor were collected and analyzed for composition. The results are summarized in the following table.

(62) TABLE-US-00007 Liquid Feed Phase Vapor Phase Methylcyclopentane, % 98.24 99.57 97.78 n-Hexane, % 1.73 0.43 2.22

(63) The separation factor in the above example has been found to be 5.25

Example 7

(64) Experiments were conducted with hydrocarbon feedstock consisting of hexane and methyl cyclopentane with NMP as a solvent. The solvent-to feed ratio was 3 vol/vol. The mixture of solvent and feed were heated to a temperature of 75 C. and the vapors were condensed and completely refluxed back to the solvent feed mixture. After 2 hours of distillation and total reflux, samples of both liquid and condensed vapor were collected and analyzed for composition. The results are summarized in the following table.

(65) TABLE-US-00008 Liquid Feed Phase Vapor Phase Methylcyclopentane, % 0.74 0.82 0.37 n-Hexane, % 99.26 99.18 99.63

(66) The separation factor in the above example has been found to be 2.22

Example 8

(67) Experiments were conducted with hydrocarbon feedstock consisting of hexane and methyl cyclopentane with NMP as a solvent. The solvent-to feed ratio was 3 vol/vol. The mixture of solvent and feed were heated to a temperature of 75 C. and the vapors were condensed and completely refluxed back to the solvent feed mixture. After 2 hours of distillation and total reflux, samples of both liquid and condensed vapor were collected and analyzed for composition. The results are summarized in the following table.

(68) TABLE-US-00009 Liquid Feed Phase Vapor Phase Methylcyclopentane, % 90.45 91.35 82.81 n-Hexane, % 9.55 8.65 17.19

(69) The separation factor in the above example has been found to be 2.19

Example 9

(70) Experiments were conducted with hydrocarbon feedstock consisting of hexane and methyl cyclopentane with Sulfolane as a solvent. The solvent-to feed ratio was 3 vol/vol. The mixture of solvent and feed were heated to a temperature of 75 C. and the vapors were condensed and completely refluxed back to the solvent feed mixture. After 2 hours of distillation and total reflux, samples of both liquid and condensed vapor were collected and analyzed for composition. The results are summarized in the following table.

(71) TABLE-US-00010 Liquid Feed Phase Vapor Phase Methylcyclopentane, % 89.03 88.55 91.27 n-Hexane, % 10.97 11.44 8.73

(72) The separation factor in the above example has been found to be 0.74

Example 10

(73) Experiments were conducted with hydrocarbon feedstock consisting of hexane and methyl cyclopentane with DMSO as a solvent. The solvent-to feed ratio was 3 vol/vol. The mixture of solvent and feed were heated to a temperature of 75 C. and the vapors were condensed and completely refluxed back to the solvent feed mixture. After 2 hours of distillation and total reflux, samples of both liquid and condensed vapor were collected and analyzed for composition. The results are summarized in the following table.

(74) TABLE-US-00011 Liquid Feed Phase Vapor Phase Methylcyclopentane, % 87.54 86.81 91.04 n-Hexane, % 12.45 13.19 12.45

(75) The separation factor in the above example has been found to be 0.647

(76) The data summarized in Table II indicates that for separation of hexane from MCP for the production of high purity n-hexane, MEG, TEG and NMP acts as a better solvent compare to DMSO and Sulfolane.

(77) TABLE-US-00012 TABLE II LIQUID FEED FRACTION VAPOR (%) (%) FRACTION (%) Sep SOLVENT MCP HEXANE MCP HEXANE MCP HEXANE S/F Factor MEG 69.1 30.9 58.23 41.77 72.41 27.59 3 1.88 TEG 12.09 87.91 6.93 93.61 13.51 86.48 3 2.29 NMP 9.49 90.51 10.21 89.79 2.89 97.10 3 3.81 SULFOLANE 10.44 89.56 10.89 89.10 8.30 91.70 3 1.35 DMSO 10.18 89.02 10.23 89.77 9.94 90.05 3 1.03 MEG 98.24 1.73 99.57 0.43 97.78 2.22 3 5.25 NMP 0.74 99.26 0.82 99.18 0.37 99.63 3 2.22 NMP 90.45 9.55 91.35 8.65 82.81 17.19 3 2.19 SULFOLANE 89.03 10.97 88.55 11.44 91.27 8.73 3 0.74 DMSO 87.54 12.45 86.81 13.19 91.04 8.96 3 0.64 *S/F is solvent to feed ratio

Example 11

(78) Experiments were conducted with hydrocarbon feedstock consisting of cyclohexane and iso-heptane with MEG as a solvent. The solvent-to feed ratio was 3 vol/vol. The mixture of solvent and feed were heated to a temperature of 80 C. and the vapors were condensed and completely refluxed back to the solvent feed mixture. After 2 hours of distillation and total reflux, samples of both liquid and condensed vapor were collected and analyzed for composition. The results are summarized in the following table.

(79) TABLE-US-00013 Feed Liquid Phase Vapor Phase Cyclohexane 84.59 85.87 83.97 Iso-heptanes 15.41 14.13 16.03

(80) The separation factor in the above example has been found to be 1.16

Example 12

(81) Experiments were conducted with hydrocarbon feedstock consisting of cyclohexane and iso-heptanes with MEG as a solvent. The solvent-to feed ratio was 3 vol/vol. The mixture of solvent and feed were heated to a temperature of 80 C. and the vapors were condensed and completely refluxed back to the solvent feed mixture. After 2 hours of distillation and total reflux, samples of both liquid and condensed vapor were collected and analyzed for composition. The results are summarized in the following table.

(82) TABLE-US-00014 Feed Liquid Phase Vapor Phase Cyclohexane 98.98 99.3 98.35 Iso-heptanes 1.02 0.7 1.65

(83) The separation factor in the above example has been found to be 2.37.

Example 13

(84) Experiments were conducted with hydrocarbon feedstock consisting of cyclohexane and iso-heptanes with NMP as a solvent. The solvent-to feed ratio was 3 vol/vol. The mixture of solvent and feed were heated to a temperature of 80 C. and the vapors were condensed and completely refluxed back to the solvent feed mixture. After 2 hours of distillation and total reflux, samples of both liquid and condensed vapor were collected and analyzed for composition. The results are summarized in the following table.

(85) TABLE-US-00015 Feed Liquid Phase Vapor Phase Cyclohexane 90.09 90.41 87.28 Iso-heptanes 9.91 9.59 12.72

(86) The separation factor in the above example has been found to be 1.37.

Example 14

(87) Experiments were conducted with hydrocarbon feedstock consisting of cyclohexane and iso-heptanes with NMP as a solvent. The solvent-to feed ratio was 3 vol/vol. The mixture of solvent and feed were heated to a temperature of 80 C. and the vapors were condensed and completely refluxed back to the solvent feed mixture. After 2 hours of distillation and total reflux, samples of both liquid and condensed vapor were collected and analyzed for composition. The results are summarized in the following table.

(88) TABLE-US-00016 Feed Liquid Phase Vapor Phase Cyclohexane 97.17 99.32 98.48 Iso-heptanes 0.83 0.67 1.51

(89) The separation factor in the above example has been found to be 2.25.

Example 15

(90) Experiments were conducted with hydrocarbon feedstock consisting of cyclohexane and iso-heptanes with DMSO as a solvent. The solvent-to feed ratio was 3 vol/vol. The mixture of solvent and feed were heated to a temperature of 80 C. and the vapors were condensed and completely refluxed back to the solvent feed mixture. After 2 hours of distillation and total reflux, samples of both liquid and condensed vapor were collected and analyzed for composition. The results are summarized in the following table.

(91) TABLE-US-00017 Feed Liquid Phase Vapor Phase Cyclohexane 90.45 90.69 89.29 Iso-heptanes 9.55 9.30 10.71

(92) The separation factor in the above example has been found to be 1.17.

Example 16

(93) Experiments were conducted with hydrocarbon feedstock consisting of cyclohexane and iso-heptanes with Sulfolane as a solvent. The solvent-to feed ratio was 3 vol/vol. The mixture of solvent and feed were heated to a temperature of 80 C. and the vapors were condensed and completely refluxed back to the solvent feed mixture. After 2 hours of distillation and total reflux, samples of both liquid and condensed vapor were collected and analyzed for composition. The results are summarized in the following table.

(94) TABLE-US-00018 Feed Liquid Phase Vapor Phase Cyclohexane 89.50 89.67 87.77 Iso-heptanes 10.59 10.33 12.22

(95) The separation factor in the above example has been found to be 0.826.

(96) The data summarized in Table III indicates that for separation of Cyclohexane from iso-heptane, MEG, TEG and NMP are better solvent compare to DMSO and Sulfolane

(97) TABLE-US-00019 TABLE III LIQUID VAPOR FEED FRACTION FRACTION (%) (%) (%) Sep SOLVENT Chex i-hep Chex i-hep Chex i-hep S/F Factor MEG 84.59 15.41 85.87 14.13 83.97 16.03 3 1.16 TEG 98.98 1.02 99.3 0.7 98.35 1.65 3 2.37 NMP 90.09 9.91 90.41 9.59 87.28 12.72 3 1.37 NMP 99.17 0.83 99.32 0.68 98.48 1.51 3 2.25 SULFOLANE 89.50 10.59 89.67 10.33 87.77 12.22 3 0.826 DMSO 90.45 9.55 90.69 9.31 89.29 10.71 3 1.17

(98) Simulation studies were also carried out with Aspen to simulate the flow scheme given in FIG. 1. Studies were done to determine the number of theoretical stage that are required in each column of extractive distillation and recovery of solvent and recycle. The result indicated that the cyclohexane is recovered at the bottom of column [8] along with the solvent and solvent free iso-heptane at the top of same column. Methylcyclopentane with solvent and solvent free High purity n-hexane (also referred as hexane) is also recovered at the bottom and top of column [7] respectively. The simulation also confirmed that the solvent can be recovered and recycled. After solvent recovery, solvent free cyclohexane and methylcyclopentane are recovered in column [16] and [15] respectively. The simulation results were in line with the experimental data and validated the experiment findings.

(99) Accordingly, the present invention relates to a process which is useful for isolation of pure methylcyclopentane, pure iso-heptane and pure cyclohexane along with the pure n-hexane.