JP2009275019A - Method for refining water-alcohol composition - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for efficiently refining, with less energy consumption, a composition comprising ethanol, 1-butanol, other organic compound(s) and water for the purpose of separating ethanol, 1-butanol and the other components from the composition, to provide a method for efficiently producing 1-butanol from ethanol, and to provide a production system to be used therefor. <P>SOLUTION: The method for refining the composition comprising ethanol, 1-butanol, other organic compound(s) and water (a water-alcohol composition) for the purpose of separating ethanol, 1-butanol and the other components from the composition is provided, comprising refining the ethanol and/or 1-butanol by distillation after undergoing the step of removing water from the composition. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

The present invention relates to a method for efficiently purifying 1-butanol from a composition containing water, ethanol and 1-butanol.

From the viewpoint of preventing global warming, in order to prevent the increase of carbon dioxide, a kind of greenhouse gas in the atmosphere, the raw materials used in the production of chemicals are changed from fossil-derived materials such as petroleum and coal to plant-derived carbon materials. There is a wide range of research and practical application.

  Today, the production of chemicals, mainly made from petroleum, has evolved with decades of history, creating sophisticated manufacturing processes that reduce energy consumption. However, since plant-derived raw materials are different from conventional petroleum-derived materials, it is necessary to construct a new production process.

  Production of so-called bioethanol obtained from saccharides is one of plant-derived compounds that are already widely used, but since ethanol is a compound of two carbons, in order to be widely used as a chemical raw material, It is necessary to carry out a carbon increase reaction that increases carbon-carbon bonds.

  Examples of the carbon increase reaction of ethanol include a method using a hydroxyapatite catalyst as a method for producing 1-butanol by dehydration between molecules (Patent Document 1, Patent Document 2), and a catalyst having a metal nitrate supported on γ-alumina. There is known a method using the method (Patent Document 3). However, it is disclosed that if the conversion rate of ethanol as a raw material is increased to some extent, the yield of 1-butanol is not improved, and by-products that have further increased the carbon number increase (Patent Document 2). .

  Therefore, in order to obtain a target compound such as 1-butanol with high purity and good yield, the reaction is performed at a low conversion rate, unconverted ethanol, 1-butanol as a product, alcohol having 5 or more carbon atoms, etc. It can be seen that ethanol, 1-butanol, other products, and water are separated from the other product and the composition containing water, and ethanol is a preferred production form to be reused as a raw material.

International Patent Publication WO99-38822 International Patent Publication WO2006-059729 Chinese Patent CN1528727

  An object of the present invention is to provide an efficient purification method with less energy consumption in order to separate ethanol, 1-butanol, other organic compounds and water into a composition containing ethanol, 1-butanol and other components. The purpose is to provide. It is another object of the present invention to provide a method for efficiently producing 1-butanol from ethanol and a production apparatus used.

  In order to separate ethanol, 1-butanol, and other components from a composition containing ethanol, 1-butanol, other organic compounds, and water (hereinafter sometimes referred to as a water-alcohol composition). As a result of diligent examination of this method, it was found that water contained in ethanol as a raw material and water produced by the reaction made it difficult to purify ethanol and 1-butanol, and at least water was removed from the water-alcohol composition. It has been found that high purity 1-butanol can be obtained efficiently by performing a purification step such as distillation after the step of causing the step of distillation.

Furthermore, it discovered that 1-butanol could be efficiently manufactured from ethanol by using the said method, and came to completion of this invention.
That is, the following method was invented as means for solving the above-mentioned problems.

  (1) In a method for separating ethanol, 1-butanol, other organic compounds, and water (water-alcohol composition) into ethanol, 1-butanol and other components, at least water from the composition A method of purifying ethanol and / or 1-butanol by distillation after the step of removing water.

  (2) The purification according to (1), wherein the step of removing at least water from the water-alcohol composition uses at least one selected from a separation membrane device, an azeotropic distillation device, and a dehydrating device using a dehydrating agent. Method.

  (3) The purification method according to (1) or (2), wherein the water-alcohol composition is a composition obtained by bringing ethanol into contact with a solid catalyst.

  (4) A method for producing 1-butanol from ethanol, comprising a step of recycling a part or all of ethanol obtained by the purification method according to (1) or (2) to a raw material for reaction with a solid catalyst.

  (5) A reactor for bringing ethanol into contact with a solid catalyst, a separation membrane device, an azeotropic distillation device, a dehydrating device using a dehydrating agent, and a distillation for purifying ethanol and / or 1-butanol. An apparatus for producing 1-butanol from ethanol having an apparatus and a recycle line for recycling ethanol obtained from the distillation apparatus.

  According to the present invention, since 1-butanol is extracted from a water-alcohol composition containing water, ethanol, and 1-butanol, it can be purified efficiently with low energy consumption. Moreover, 1-butanol can be efficiently produced from ethanol in high yield.

  In the present invention, the water-alcohol composition includes at least ethanol, 1-butanol, and water, in addition to aliphatic alcohols having 5 or more carbon atoms, aliphatic aldehydes, aliphatic olefins, aromatic compounds, and the like. May be included.

  Examples of the aliphatic alcohol having 5 or more carbon atoms include 1-hexanol, 1-octanol, 2-ethyl-1-butanol, 2-ethyl-1-hexanol and the like, and examples of the aliphatic aldehyde include acetaldehyde, butyl Examples of the aliphatic olefin include butene, hexene, octene, and butadiene, and examples of the aromatic compound include benzene, toluene, xylene, and benzaldehyde.

  The step of removing at least water from the water-alcohol composition refers to a step of separating water and 1-butanol. In addition to the step of separating the water-alcohol composition into water and other components, water and A step of separating ethanol into 1-butanol and other components is also included.

  The water content in the dehydrated composition obtained through the step of removing at least water from the water-alcohol composition is preferably 5% by weight or less, more preferably 4% by weight or less, and further preferably 3% by weight or less. preferable. Although it is preferable that the water content in the dehydrated composition is small, it is also removed in a distillation step for purifying ethanol and / or 1-butanol, which will be described later, and excessive dehydration treatment removes 1-butanol together with water. In general, it is preferably 0.01% by weight or more, more preferably 0.1% by weight or more, and more preferably 0.5% by weight. The above is more preferable.

  As an apparatus for removing water from the water-alcohol composition, it is preferable to use at least one apparatus selected from a membrane separation apparatus, an azeotropic distillation apparatus, and a dehydrating apparatus using a dehydrating agent.

  As the membrane separation device, a known device having the ability to separate water and alcohol can be used. For example, a pervaporation separation method using an asymmetric separation membrane made of an aromatic polyimide disclosed in JP-A-3-284336, or an aroma having gas permeation performance disclosed in JP-A-5-177111. Examples include a method using a separation membrane module containing a gas separation membrane made of a group polyimide, a pervaporation dehydration purification method using a zeolite membrane disclosed in JP-A-9-131516, and the like.

  As an azeotropic distillation apparatus, water is removed from the water-alcohol composition by azeotropic distillation using a hydrophobic azeotropic solvent known to form an azeotropic composition with water such as benzene and cyclohexane. In addition, the azeotropic gas is exemplified by a form in which the azeotropic solvent separated by the oil / water separator after the cooling is reused.

  The dehydrating apparatus using the dehydrating agent may be in any form as long as it is of a type that uses an insoluble dehydrating agent in the water-alcohol composition such as zeolite, but a plurality of dehydrating apparatuses filled with the dehydrating agent. A method of continuously operating while switching between the dehydration process and the regeneration process is preferable.

  In the step of removing water, one or more of the above devices may be used, and two or more of these devices may be used in combination as necessary.

  Purified ethanol by separating the composition obtained by the dehydration treatment (hereinafter sometimes referred to as dehydrated composition) into ethanol, 1-butanol, and other compositions by distillation operation. And 1-butanol can be obtained.

  Using two or more distillation towers, first, the dehydrated composition is separated into light boiling components such as ethanol and aliphatic olefins and other components including 1-butanol and aliphatic alcohols having 5 or more carbon atoms, and the like. Next, the other components are separated into 1-butanol and a heavy boiling component such as an aliphatic alcohol having 5 or more carbon atoms, whereby high-purity ethanol and 1-butanol are obtained. In order to increase the purity of the obtained ethanol or 1-butanol, a distillation or dehydration treatment step may be further performed, and an aliphatic alcohol having 5 or more carbon atoms or the like is obtained by performing a purification treatment of a heavy boiling component in a distillation tower. You can also get it. In order to reduce the utility required for distillation, an internal heat exchange distillation column can be used. Further, the top condenser of one distillation column can be used as a reboiler for another distillation column.

  The water-alcohol composition may be a composition obtained by any method, but is preferably a composition obtained by contacting ethanol with a solid catalyst.

  Examples of the solid catalyst include a catalyst containing a specific hydroxyapatite disclosed in Patent Document 1 and Patent Document 2, and a catalyst obtained by firing a metal nitrate supported on γ-alumina disclosed in Patent Document 3. Is exemplified.

  Further, a weakly basic catalyst in which a basic component such as an alkali metal such as cesium is supported on zeolite can also be exemplified.

  In the method of bringing ethanol into contact with the solid catalyst, ethanol is preferably in a gaseous state, and the raw material gas containing the ethanol gas may contain components other than ethanol.

  When a large amount of non-condensable gas such as nitrogen is contained as a component other than ethanol, a collection step is applied to the reaction gas obtained by bringing ethanol into contact with the solid catalyst. Thus, a water-alcohol composition can be obtained.

  The collecting step may be in any form as long as the reaction gas and the collected liquid are brought into contact with each other. For example, the flow of the collected liquid and the flow of the reactive gas are countercurrently or cocurrently flowed. Examples include a step of using a collection device such as a packed tower, a multi-tube wet wall tower, a spray tower, a bubble bell tower, or a bubble tower for blowing the reaction gas into a collection liquid.

  The collection liquid is not particularly limited as long as it does not contain a large amount of water or a compound that forms an irreversible reaction product under the collection conditions. The collection liquid may be a dedicated collection liquid, or high boiling point components generated in the purification process of 1-butanol, 1-butanol obtained in the purification process, or 1-butanol with low purity. A part or all of them can be used as a collecting liquid. The liquid after collection obtained by contacting with the collection liquid is also referred to as a water-alcohol composition in the present invention.

  When there is little or no non-condensable gas as a component other than ethanol, ethanol and the solid catalyst can be brought into contact under reduced pressure conditions, and under these conditions, the non-condensable gas The content is preferably 10% by volume or less, more preferably 5% by volume or less, and still more preferably 1% by volume or less.

  When a condensable component is present in a large amount as a component other than ethanol, a large amount of energy is required for gasification and liquefaction of the condensable component. Therefore, the content of the component is preferably 50% by volume, and 30% by volume. % Or less is preferable, and 20% by volume or less is more preferable.

  When the reaction is carried out under reduced pressure conditions, it is kept in a gas state under reduced pressure until the water is removed, and then cooled and the pressure is increased to at least normal pressure to liquefy. By doing so, a form of obtaining a liquid dehydrated composition is preferred, but the collecting step may be performed.

  The preferable range of the reduced pressure condition is 1 kPa to 90 kPa, more preferably 5 kPa to 85 kPa, still more preferably 10 kPa to 80 kPa, and most preferably 15 kPa to 75 kPa, in terms of the pressure at the reactor inlet.

Next, a reactor for bringing ethanol into contact with a solid catalyst, at least one dehydration device selected from a separation membrane device, an azeotropic distillation device, and a dehydration device using a dehydrating agent, and a distillation for purifying ethanol and / or 1-butanol An apparatus for producing 1-butanol from ethanol having an apparatus and a recycle line for recycling ethanol obtained from the distillation apparatus will be described below.
In FIG. 1, the water-alcohol composition obtained in the reactor 104 is separated into a membrane passage component such as water and a membrane non-passage component such as ethanol and 1-butanol by the separation membrane device 106. The water inside is mainly collected by the collecting tube 114 and then discharged, and the component that does not pass through the membrane is collected by the collecting tube 109 and then sent to the ethanol recovery tower 111 by the reaction liquid transfer pump 110.

  The inside of the system from the pressure control valve 102 at the reactor inlet to the suction part of the vacuum pump 116 and the gas phase part of the collection pipe 109 is kept at a reduced pressure, and before and after the membrane of the membrane separation device 106 by the pressure control valves 108 and 115. The pressure difference is adjusted.

In the ethanol recovery tower 111, a light component mainly composed of ethanol and a heavy component mainly composed of 1-butanol are separated, and the light component is recycled as a reaction raw material via an ethanol tank 117. On the other hand, the heavy component is separated into 1-butanol and a high boiling point component by the butanol purification tower 112.
In FIG. 2, by replacing the ethanol recovery column 111 and the butanol purification column 112 in FIG. 1 with a Petrique type distillation column, ethanol from the top, butanol from the middle, and higher boiling point components from the bottom can be obtained.
In FIG. 3, the water-alcohol composition is liquefied and recovered in the flash tower 308 and then sent to the ethanol recovery tower 309, where an ethanol aqueous solution is obtained from the top and a 1-butanol solution is obtained from the bottom.

The aqueous ethanol solution is separated as water by the ethanol purification tower 313 and then recycled as a reaction raw material via the alcohol tank 314. On the other hand, the 1-butanol solution is a 1-butanol / water azeotrope component in the water separation tower 310. After a dehydration process for separating water by 311 is performed, 1-butanol and a high boiling component are separated in a butanol purification tower 312.
In FIG. 4, the water-alcohol composition obtained by the collection tube 409 is transferred to the azeotropic distillation column 411 by the reaction liquid transfer pump 410. The water separated in the azeotropic distillation tower 411 is discharged from the bottom of the water recovery tower 415 through the phase separation tank 413 and the azeotropic solvent recovery tower 414. The azeotropic solvent is recycled to the top of the phase separation tanks 413 to 411, and the remaining azeotropic solvent dissolved in the aqueous ethanol solution separated from 413 is recycled from the top of the 414, and therefore hardly flows out of the system.

A composition comprising ethanol, 1-butanol and a high-boiling component obtained from the bottom of the azeotropic distillation column 411 is separated into ethanol, 1-butanol and a high-boiling component by a Petrique distillation column 416, respectively. It is recycled as a reaction raw material via 417.
FIG. 5 shows a flow in the case where a non-condensable gas is used as a diluent gas and a high boiling point component obtained from the butanol purification tower 512 is used as a collecting liquid in the collecting tower 506.

  The gaseous composition comprising the water-alcohol composition and the non-condensable gas obtained in the reactor 503 separates the non-condensable gas in the collection tower 506 and sends it to the ethanol recovery tower 509 by the reaction liquid transfer pump 507. Then, it is separated into ethanol, water, 1-butanol and a high boiling point component, and a part of the high boiling point component is sent to the collection tower 506 as a collection liquid.

In addition, by providing an exhaust gas combustor and an air introduction line (not shown) in the non-condensable gas discharge line at the top of the collector 506, organic substances accompanying the non-condensable gas separated by the collector 506 It is also possible to use it as a diluent gas after burning.
In FIG. 6, the water-alcohol composition obtained by the reaction is separated into water, ethanol, 1-butanol and a high-boiling component by the ethanol / water separation tower 612, and the former is separated from the water by the membrane separation device 614. After being separated into ethanol, ethanol is recycled as a reaction raw material via an alcohol tank 620, and the latter is separated into 1-butanol and a high-boiling component by a butanol purification tower 613. In the figure, the vacuum pumps 609 and 618 can also be used together.
In FIG. 7, the water-alcohol composition sent to the ethanol / water separation tower 712 by the reaction liquid transfer pump 710 is separated into water, ethanol, 1-butanol, and high-boiling components, and the former is an ethanol selective permeation type. After being separated into water and ethanol by the membrane separator 714, the ethanol is recycled as a reaction raw material via the alcohol tank 721, and the latter is separated into 1-butanol and a high boiling point component by the butanol purification tower 713. In the figure, the vacuum pumps 708 and 719 can be used as a single unit.

  Purity is 99.9% by purifying by distillation from an alcohol composition (composition 1) composed of ethanol and 1-butanol and a water-alcohol composition (composition 2) composed of ethanol, 1-butanol and water. The loss of 1-butanol when the above 1-butanol was obtained was simulated using Aspen Plus (version 2006). Using a non-random two-liquid (NRTL) activity coefficient model for gas-liquid equilibrium (VLE), the number of theoretical stages is 20, the feed stage is 10 and the reflux ratio is 1, and the 1-butanol loss ratio from the top is estimated. The results are shown in Table 1.

  As shown in Table 1, it can be seen that the composition 2 containing water has a significant loss of 11.6% of the supply amount, whereas it does not contain a loss of 0.7% if water is not included.

It is a figure which shows the method of manufacturing 1-butanol from ethanol which has the process of using a water permselective membrane for dehydration which is one Embodiment of this invention. It is a figure which shows the method of manufacturing 1-butanol from ethanol which has the process of performing ethanol collection | recovery and butanol refinement | purification in one distillation column using the Petrique type | mold distillation column which is another embodiment of this invention. It is a figure which shows the method of manufacturing 1-butanol from ethanol which has the process which combined distillation and phase separation which is another embodiment of this invention. It is a figure which shows the method of manufacturing 1-butanol from ethanol which has the process of the dehydration process by azeotropic distillation which is another embodiment of this invention. It is a figure which shows the method of manufacturing 1-butanol from ethanol which has the process of using the non-condensable gas as dilution gas and using the produced | generated high boiling-point component as a collection liquid which is another embodiment of this invention. It is a figure which shows the method of manufacturing 1-butanol from ethanol which has the process of using a water permselective membrane as a dehydration process of the water-ethanol composition which is another embodiment of this invention. It is a figure which shows the method of manufacturing 1-butanol from ethanol which has the process of using an ethanol permselective membrane for dehydration which is another embodiment of this invention.

Explanation of symbols

101, 201, 301, 401, 501, 601, 701 Ethanol transfer metering pumps 102, 202, 302, 402, 602, 702 Pressure regulating valves 103, 203, 303, 403, 502, 603, 703 Ethanol heating heater 104, 204, 304, 404, 503, 604, 704 Reactors 105, 205, 305, 306, 405, 504, 508, 606, 705 Coolers 106, 206, 614 Separation membrane devices 107, 113, 207, 213, 406, 412,505,607,615,619,706,715,716 Condensers 108,115,208,215,407,608,617,707,718 Pressure control valve 109,114,209,214,409,610,709 Collection tubes 110, 210, 10, 507, 611, 710 Reaction liquid transfer pump 111, 309, 509 Ethanol recovery tower 112, 312, 512, 613, 713 Butanol purification tower 116, 216, 307, 408, 609, 618, 708, 719 Vacuum pump 117, 217, 314, 417, 514, 620, 721 Alcohol tank 211, 416 Petrique type distillation tower 308 Flash tower 310, 510 Water separation tower 311, 413, 511 Phase separation tank 313, 513 Ethanol purification tower 411 Azeotropic distillation tower 414 Boiling solvent recovery tower 415 Water recovery tower 506 Collection tower 612, 712 Ethanol / water separation tower 714 Selective ethanol selective membrane 616, 717 Collector 720 Recovery ethanol feed pump

Claims (5)

In a method for separating ethanol, 1-butanol, other organic compounds, and water (water-alcohol composition) into ethanol, 1-butanol, and other components, at least water is removed from the composition. A method for purifying ethanol and / or 1-butanol by distillation after passing through the steps. The purification method according to claim 1, wherein the step of removing at least water from the water-alcohol composition uses at least one selected from a separation membrane apparatus, an azeotropic distillation apparatus, and a dehydrating apparatus using a dehydrating agent. The purification method according to claim 1 or 2, wherein the water-alcohol composition is a composition obtained by bringing ethanol and a solid catalyst into contact with each other. A method for producing 1-butanol from ethanol, comprising a step of recycling a part or all of ethanol obtained by the purification method according to claim 1 or 2 to a raw material for a reaction with a solid catalyst. A reactor in which ethanol and a solid catalyst are contacted, a separation membrane device, an azeotropic distillation device, at least one type of dehydration device selected from dehydration devices using a dehydrating agent, and a distillation device for purifying ethanol and / or 1-butanol; An apparatus for producing 1-butanol from ethanol having a recycle line for recycling ethanol obtained from the distillation apparatus.

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