JPS6225984A - Method of concentrating and purifying alcohol - Google Patents
Method of concentrating and purifying alcoholInfo
- Publication number
- JPS6225984A JPS6225984A JP60165978A JP16597885A JPS6225984A JP S6225984 A JPS6225984 A JP S6225984A JP 60165978 A JP60165978 A JP 60165978A JP 16597885 A JP16597885 A JP 16597885A JP S6225984 A JPS6225984 A JP S6225984A
- Authority
- JP
- Japan
- Prior art keywords
- alcohol
- impurities
- water
- tank
- dissolving solvent
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Pending
Links
Classifications
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E50/00—Technologies for the production of fuel of non-fossil origin
- Y02E50/10—Biofuels, e.g. bio-diesel
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02P—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
- Y02P20/00—Technologies relating to chemical industry
- Y02P20/50—Improvements relating to the production of bulk chemicals
- Y02P20/54—Improvements relating to the production of bulk chemicals using solvents, e.g. supercritical solvents or ionic liquids
Landscapes
- Preparation Of Compounds By Using Micro-Organisms (AREA)
- Distillation Of Fermentation Liquor, Processing Of Alcohols, Vinegar And Beer (AREA)
- Extraction Or Liquid Replacement (AREA)
- Organic Low-Molecular-Weight Compounds And Preparation Thereof (AREA)
Abstract
Description
【発明の詳細な説明】
〔産業上の利用分野〕
本発明は、発酵アルコール等から、高純度のアルコール
を省エネルギー的に濃縮精製し得る方法に関する。DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to a method for concentrating and purifying highly pure alcohol from fermented alcohol and the like in an energy-saving manner.
甘しよ、さつまいも、とうもろこし等の炭水化物を原料
とする発酵アルコールは、飲料用及び工業用として重要
な出発原料であるが、発酵法で得られるアルコール水溶
液のアルコール濃度は10〜20 yt%と低いため、
約95〜100vt%まで濃縮する必要がある。Fermented alcohol made from carbohydrates such as amashiyo, sweet potato, and corn is an important starting material for beverages and industrial use, but the alcohol concentration of the alcohol aqueous solution obtained by the fermentation method is as low as 10 to 20 yt%. For,
It is necessary to concentrate to about 95-100 vt%.
従来、この濃縮法として蒸留法が用いられてきたが、大
部分を占める水も80〜100℃まで昇温せねばならず
、経済的に不利であシ、これに替わる省エネルギー型の
濃縮法の開発が望まれている。Conventionally, distillation has been used as a concentration method, but water, which makes up most of the water, must be heated to 80 to 100°C, which is economically disadvantageous, and an energy-saving concentration method has been proposed instead. Development is desired.
従来、省エネルギー型の濃縮法として超臨界状態又は擬
臨界状態の炭酸ガス、エチレン、エタンを用いてアルコ
ールを水より抽出・分離して濃縮する方法が提案されて
いる。(特開昭56−56201及び同59−1415
28号公報)しかしながら、この方法で濃縮された発酵
アルコール中には高沸点不純物(04〜(:!5系7−
ゼル油)等の副生成物が混入しておシ、これらも分離除
去する必要があるが、この分離除去法として従来は蒸留
法による精留塔が用いられているが、との際、濃縮アル
コールを再昇温し、蒸発及び凝縮を行なわせねばならず
熱負荷が増大し、全体として省エネルギー的な方法と云
えないという欠点があった。BACKGROUND ART Conventionally, as an energy-saving concentration method, a method has been proposed in which alcohol is extracted and separated from water using carbon dioxide, ethylene, or ethane in a supercritical or quasi-critical state and concentrated. (Unexamined Japanese Patent Publication No. 56-56201 and No. 59-1415
However, the fermented alcohol concentrated by this method contains high boiling point impurities (04~(:!5 series 7-
If by-products such as zel oil are mixed in, these also need to be separated and removed. Conventionally, a rectification column using a distillation method has been used to separate and remove them. This method has the disadvantage that the alcohol has to be heated again and evaporated and condensed, increasing the heat load, and that it cannot be said to be an energy-saving method as a whole.
本発明は上記した超臨界状態又は擬臨界状態の炭酸ガス
、エチレン、エタンなどを用いてアルコールを水より分
離して得た濃縮アルコールから省エネルギー的に、実質
的に水、高沸点不純物を含まない濃縮アルコールを得る
方法を提供しようとするものである。The present invention uses concentrated alcohol obtained by separating alcohol from water using supercritical or quasi-critical carbon dioxide, ethylene, ethane, etc. in an energy-saving manner and substantially contains no water or high-boiling point impurities. It is intended to provide a method for obtaining concentrated alcohol.
すなわち本発明はアルコール、高沸点不純物からなる有
機液体溶質及び水とよりなる混合物に、溶解溶剤を加え
、該溶解溶剤の超臨界状態又は擬臨界状態になる条件で
接触させて混合物を形成させ、該混合物を第1抽出分離
槽に導いて、水を主成分とし大部分の高沸点不純物、一
部のアルコール、溶解溶剤を含有する重液と、溶解溶剤
を主成分とし大部分のアルコール、一部の高沸点不純物
を含有する軽液に分離させ、該軽液を該第1抽出分離槽
より抜出して不純物分離槽に導き、該不純物分離槽を減
圧させることにより実質的に高沸点不純物を含まず水分
が除去されたアルコールと実質的に水と高沸点不純物と
少量のアルコールを含有する液とに分離し、前者を濃縮
精製アルコールとして回収し、後者を前記第1抽出分離
槽からの重液と混合し、該混合液に再度前記溶解溶剤を
超臨界状態又は擬臨界状態になる条件で接触させて混合
物を形成させ、該混合物を第2抽出分離槽で実質的に水
と高沸点不純物よりなる重液と実質的に溶解溶剤とアル
コールよりなる軽液に分離し、後者の軽液を前記第1抽
出分離槽に循環させることを特徴とするアルコール濃縮
精製方法でおる。That is, the present invention adds a dissolving solvent to a mixture of alcohol, an organic liquid solute consisting of high-boiling point impurities, and water, and forms a mixture by contacting the dissolving solvent under conditions that bring the dissolving solvent into a supercritical or quasi-critical state. The mixture is led to a first extraction separation tank, and a heavy liquid containing water as the main component and most of the high-boiling point impurities, some alcohol, and a dissolving solvent, and a heavy liquid that is mainly composed of water and containing most of the alcohol and a dissolving solvent are separated. The light liquid is extracted from the first extraction separation tank and introduced into the impurity separation tank, and the impurity separation tank is depressurized to substantially contain the high-boiling impurities. The alcohol from which water has been removed is separated into a liquid containing substantially water, high-boiling point impurities, and a small amount of alcohol, the former is recovered as concentrated purified alcohol, and the latter is collected as a heavy liquid from the first extraction separation tank. The mixture is again brought into contact with the dissolving solvent under conditions of a supercritical state or a quasi-critical state to form a mixture, and the mixture is substantially separated from water and high-boiling point impurities in a second extraction separation tank. This alcohol concentration and purification method is characterized in that the alcohol is separated into a heavy liquid consisting of a dissolving solvent and a light liquid consisting essentially of a dissolving solvent and alcohol, and the latter light liquid is circulated to the first extraction separation tank.
本発明で使用する溶解溶剤としては、アルコールを良く
溶かし、水及び重質不純物を溶かしにくい溶剤が用いら
れ、特開昭56〜56021号公報にみられるCO2や
炭素数2〜4のf?vllk、02B6のような炭化水
素及びこれらの混合物などの他に、臨界温度がアルコー
ルの沸点以下である無機又は有機の溶剤又はこれらの混
合溶剤が使用可能である。下表に主な溶剤を示す。The dissolving solvent used in the present invention is a solvent that dissolves alcohol well but does not easily dissolve water and heavy impurities. In addition to hydrocarbons such as Vllk, 02B6, and mixtures thereof, inorganic or organic solvents having a critical temperature below the boiling point of alcohol, or mixed solvents thereof can be used. The table below shows the main solvents.
溶剤基 臨界温度
Co231.I
C,H,9,7
02馬 514
0sH692,3
03H896,8
04HI0 152.0
溶解溶剤としては、臨界温度が常温に近い程、またアル
コールとの親和力の大きいもの程、省エネルギー効果が
大きいので好ましい。一般に溶解溶剤は原料アルコール
1重量部に対して2〜6重量部添加されるが、アルコー
ルとの親和力の大きい溶解溶剤の場合は、その添加量は
上記範囲より小にすることができる。Solvent base Critical temperature Co231. I C, H, 9, 7 02 horses 514 0sH692, 3 03H896, 8 04HI0 152.0 As a dissolving solvent, the closer the critical temperature is to room temperature and the greater the affinity with alcohol, the greater the energy saving effect, so it is preferable. . Generally, 2 to 6 parts by weight of the dissolving solvent is added to 1 part by weight of the raw material alcohol, but in the case of a dissolving solvent having a high affinity with alcohol, the amount added can be smaller than the above range.
本発明にいう超臨界状態とは、溶解溶剤の臨界温度以上
かつ臨界圧力以上の温度、圧力条件での状態を意味し、
擬臨界状態とは、溶解溶剤の臨界温度Tc以下で、対臨
界温度Tr = T/Tc (但し0.90 < Tr
< 1.0 )の温度Tで、圧力はその温度における溶
解溶剤の飽和蒸気圧以上の状態を意味する。擬臨界状態
では超臨界状態より溶解溶剤の溶解度が増す場合がある
が、溶解速度は減少する傾向にある。The supercritical state as used in the present invention refers to a state under temperature and pressure conditions that are higher than the critical temperature and critical pressure of the dissolving solvent,
The quasi-critical state is below the critical temperature Tc of the dissolving solvent, with respect to the critical temperature Tr = T/Tc (however, 0.90 < Tr
At a temperature T of <1.0), the pressure means a state equal to or higher than the saturated vapor pressure of the dissolving solvent at that temperature. Although the solubility of the dissolving solvent may increase in the quasi-critical state compared to the supercritical state, the dissolution rate tends to decrease.
以下、本発明の一実施態様を第1図に従って詳述する。Hereinafter, one embodiment of the present invention will be described in detail with reference to FIG.
第1図において、1は原料である発酵アルコールの供給
ライン、2は溶解溶剤の供給ライン、3は発酵アルコー
ルと溶解溶剤の混合ライン、4は混合器、5は第1抽出
分離器、6は重液取出しライン、7は軽液取出しライン
、8は減圧弁、9は不純物分離槽、10は高沸点不純物
取出しライン、11は低沸点成分(アルコール)取出し
ライン、12は高圧定量ポンプ、13は重液供給ライン
、14は溶解溶剤供給ライン、15は高沸点不純物供給
ライン、16は混合器、17は第2抽出分離器、18は
高沸点不純物取出しライン、19は低沸点成分(アルコ
ール)取出し循環ライン、20は高圧定量ポンプである
。In FIG. 1, 1 is a supply line for fermentation alcohol as a raw material, 2 is a supply line for dissolving solvent, 3 is a mixing line for fermentation alcohol and dissolving solvent, 4 is a mixer, 5 is a first extraction separator, and 6 is a Heavy liquid extraction line, 7 is a light liquid extraction line, 8 is a pressure reducing valve, 9 is an impurity separation tank, 10 is a high boiling point impurity extraction line, 11 is a low boiling point component (alcohol) extraction line, 12 is a high pressure metering pump, 13 is Heavy liquid supply line, 14 is a dissolving solvent supply line, 15 is a high boiling point impurity supply line, 16 is a mixer, 17 is a second extraction separator, 18 is a high boiling point impurity extraction line, 19 is a low boiling point component (alcohol) extraction The circulation line 20 is a high pressure metering pump.
供給ライン1より供給されたアルコール(例えば水茎8
0〜90 vt%、アルコール類:10〜20 wt%
、C4〜05系フーゼル油などの高沸点不純物: 11
j wt%)と供給ライン2より供給された溶解溶剤
とは、図示省略の高圧ポンプで圧送されて混合ライン3
で混合され、図示省略の熱交換器で温度を調整されて超
臨界状態又は擬臨界状態となって混合器4中で更に十分
混合される。混合器4はラインミキサ又はスタチックミ
キサなどが好ましいが、混合ライン3中で十分混合され
るならば必ず混合器4は必要ではない。Alcohol supplied from supply line 1 (e.g. water stem 8
0-90 vt%, alcohol: 10-20 wt%
, high boiling point impurities such as C4-05 fusel oil: 11
j wt%) and the dissolving solvent supplied from the supply line 2 are pumped by a high-pressure pump (not shown) to the mixing line 3.
The mixture is mixed in the mixer 4, and the temperature is adjusted by a heat exchanger (not shown) to reach a supercritical or quasi-critical state, and the mixture is further thoroughly mixed in the mixer 4. The mixer 4 is preferably a line mixer or a static mixer, but the mixer 4 is not necessarily required if sufficient mixing is achieved in the mixing line 3.
十分混合した液は、第1抽出分離槽5に送られ、溶解溶
剤が超臨界状態又は擬臨界状態になる条件下で十分接触
混合させられ、溶解溶剤を主成分とし濃縮された大部分
のアルコール、一部の高沸点不純物を含有する軽液と、
水を主成分とし大部分の高沸点不純物、一部のアルコー
ル、溶解溶剤を含有する重液とに分離される。The sufficiently mixed liquid is sent to the first extraction separation tank 5, where it is sufficiently contacted and mixed under conditions where the dissolving solvent becomes supercritical or quasi-critical, and most of the concentrated alcohol containing the dissolving solvent as the main component is removed. , a light liquid containing some high-boiling point impurities,
It is separated into a heavy liquid, which is mainly composed of water and contains most high-boiling point impurities, some alcohol, and a dissolving solvent.
この第1抽出分離槽5は重力沈降槽が好ましいが、混合
と抽出とと同時に行なう充填塔又は棚段塔による向流抽
出分離も有利に使用することができる。This first extraction and separation tank 5 is preferably a gravity settling tank, but countercurrent extraction and separation using a packed column or plate column in which mixing and extraction are carried out simultaneously can also be advantageously used.
前記混合器4を含め、その後流は少なくとも溶解溶剤の
超臨界状態又は擬臨界状態にある。The downstream stream including the mixer 4 is at least in a supercritical or quasi-critical state of the dissolving solvent.
すなわち混合器4では原料と溶解溶剤を十分に混合、接
触させ原料中のアルコールを溶解溶剤に抽出するが、溶
解溶剤の粘度及び表面張力を減少させ、拡散係数を増す
ことにより抽出速度を増大させることが好ましく、これ
は溶解溶剤を擬又は超臨界状態とすることによって達成
されるのである。抽出速度は超臨界状態の方が擬臨界状
態より速いので、抽出速度の点では前者の状態が好まし
い。That is, in the mixer 4, the raw material and the dissolving solvent are sufficiently mixed and contacted to extract the alcohol in the raw material into the dissolving solvent, but the extraction rate is increased by decreasing the viscosity and surface tension of the dissolving solvent and increasing the diffusion coefficient. Preferably, this is achieved by bringing the dissolving solvent into a quasi- or supercritical state. Since the extraction rate is faster in the supercritical state than in the quasi-critical state, the former state is preferable in terms of extraction rate.
次に、該軽液は7より抜き出され減圧弁8で圧力を下げ
て、不純物分離槽9に導入される。Next, the light liquid is extracted from 7, the pressure is lowered by a pressure reducing valve 8, and the light liquid is introduced into an impurity separation tank 9.
溶解溶剤の溶解度は、溶解溶剤の密度にほぼ比例してお
シ、圧力を下げるか又は温度を上げることにより溶解溶
剤の密度が低下し溶解度が低下し、一方、高沸点の物質
程溶解度の低下割合は大きいので、僅かな溶解溶剤の密
度低下によυ高沸点成分が選択的に相分離するという知
見を本発明者は得ている。The solubility of a dissolving solvent is approximately proportional to the density of the dissolving solvent, and lowering the pressure or increasing the temperature lowers the density of the dissolving solvent and decreases the solubility.On the other hand, the solubility of substances with higher boiling points decreases. Since the ratio is large, the present inventor has obtained the knowledge that υ high boiling point components undergo selective phase separation due to a slight decrease in the density of the dissolving solvent.
それ故、不純物分離槽9では、高沸点不純物(C’4〜
へ系フーゼル油)が先に相分離し、アルコールと分離さ
れる。そのため、不純物分離槽9の上部11からは、高
沸点不純物が分離された濃縮アルコールが回収される。Therefore, in the impurity separation tank 9, high boiling point impurities (C'4~
The alcohol-based fusel oil undergoes phase separation first and is separated from the alcohol. Therefore, from the upper part 11 of the impurity separation tank 9, concentrated alcohol from which high-boiling point impurities have been separated is recovered.
不純物分離槽9の圧力は、飽和圧力以上とすべきである
。それ以下に減圧すると、溶解溶剤の気化熱が必要とな
シ経済的でない。The pressure of the impurity separation tank 9 should be equal to or higher than the saturation pressure. If the pressure is reduced below that level, heat of vaporization of the dissolving solvent is required, which is not economical.
不純物分離槽9で相分離して高沸点不純物数取しライン
10から取出された高沸点不純物混合物は、一部の水と
アルコールを含んでおシ、アルコールは損失を防止する
ために回収する必要がある。そこでこの高沸点不純物混
合物は、前記第1抽出分離器5の重液取出しライン6か
ら取出される重液及び溶解溶剤供給ライン14から送供
される新たな溶解溶剤と混合器16で混合後、第2抽出
分離器17へ導入される。The high boiling point impurity mixture phase-separated in the impurity separation tank 9 and taken out from the high boiling point impurity counting line 10 contains some water and alcohol, and the alcohol needs to be recovered to prevent loss. There is. Therefore, this high-boiling point impurity mixture is mixed in the mixer 16 with the heavy liquid taken out from the heavy liquid take-out line 6 of the first extraction separator 5 and a new dissolving solvent sent from the dissolving solvent supply line 14. It is introduced into the second extraction separator 17.
第2抽出分離槽17の操作条件は、第1抽出分離槽5と
同等でも良いが、好ましくは、アルコール類に対して水
と高沸点不純物が選択的に相分離する溶解溶剤の超臨界
状態で操作するのがよい。か\る操作により第2抽出分
離槽17より、水、高沸点不純物が含まれないアルコー
ルが低沸点成分(アルコール)取出し循環ライン19よ
り回収される。しかしながら、このライン19より回収
されるアルコールはその濃度が約70%以下であるので
、濃縮アルコールとしては不十分である。そこで図示す
るように、このライン19から回収されるアルコールを
再度第1抽出分離槽5へ戻し高濃縮アルコールとしてラ
イン11よす回収するようにする。The operating conditions of the second extraction separation tank 17 may be the same as those of the first extraction separation tank 5, but preferably the operating conditions are in a supercritical state of a dissolving solvent in which water and high-boiling impurities selectively phase separate from alcohols. It's better to manipulate. Through this operation, alcohol free of water and high-boiling point impurities is recovered from the second extraction separation tank 17 through the circulation line 19 for taking out the low-boiling point component (alcohol). However, since the alcohol recovered from this line 19 has a concentration of about 70% or less, it is insufficient as concentrated alcohol. Therefore, as shown in the figure, the alcohol recovered from this line 19 is returned to the first extraction separation tank 5 again and recovered as highly concentrated alcohol through the line 11.
上記操作において、重液供給ライン13、溶解溶剤供給
ライン14及び高沸点不純物供給ライン15の交点にお
ける液は、超(擬)臨界状態になるようにすべきである
。そのため第1抽出分離器5からの重液取出しライン6
及び不純物分離槽9からの高沸点不純物取出しライン1
0にはそれぞれ高圧定量ポンプ12及び20が設けられ
ている。In the above operation, the liquid at the intersection of the heavy liquid supply line 13, the dissolving solvent supply line 14, and the high boiling point impurity supply line 15 should be brought into a super(pseudo)critical state. Therefore, the heavy liquid extraction line 6 from the first extraction separator 5
and high boiling point impurity extraction line 1 from impurity separation tank 9
0 are provided with high pressure metering pumps 12 and 20, respectively.
実施例1
第1図のフローを使用し、エタノール10wt、%、0
4〜へ系フーゼル油Q、 1 wt%、H,089,9
wt、%の原料混合物1重量部に、溶解溶剤としてco
2を6重量部加え、圧力110atm、温度40℃の超
臨界状態で30分間接触させ、重力沈降槽5で軽液と重
液に分離した。Example 1 Using the flow shown in Figure 1, ethanol 10wt, %, 0
4~He series fusel oil Q, 1 wt%, H,089,9
Co as a dissolving solvent to 1 part by weight of the raw material mixture of wt.
2 was added thereto and brought into contact for 30 minutes in a supercritical state at a pressure of 110 atm and a temperature of 40° C., and separated into a light liquid and a heavy liquid in a gravity settling tank 5.
次に、軽液を重力沈降槽5上部より抜き出し、不純物分
離槽9に導入し、温度は40℃のままで圧力を110
atmから80 atmに減圧し、04〜C5系フーゼ
ル油と水及びエタノールを含む不純物混合物が相分離槽
9上部より取シ出された。Next, the light liquid is extracted from the upper part of the gravity settling tank 5 and introduced into the impurity separation tank 9, and the pressure is increased to 110°C while keeping the temperature at 40°C.
The pressure was reduced from ATM to 80 ATM, and an impurity mixture containing 04 to C5 fusel oil, water, and ethanol was taken out from the upper part of the phase separation tank 9.
相分離槽内残存物を分析したところ、aO,以外の組成
はエタノール80%、水20%、C4〜C。Analysis of the residue in the phase separation tank revealed that the composition other than aO was 80% ethanol, 20% water, and C4-C.
系7−ゼル油検出限界以下であシ、エタノールが濃縮さ
れた。System 7 - Ethanol was concentrated below the detection limit of zel oil.
次に、前記不純物混合物と重液を混合し、該混合物1重
量部に、溶解溶剤としてC02を6重量部加え、圧力9
0 atm 、温度40℃で接触させ重力沈降槽17で
軽液と重液に分離した。Next, the impurity mixture and heavy liquid were mixed, 6 parts by weight of C02 was added as a dissolving solvent to 1 part by weight of the mixture, and the pressure was 9.
They were brought into contact at 0 atm and a temperature of 40° C. and separated into a light liquid and a heavy liquid in a gravity settling tank 17.
次に、との軽液全量と首記原料混合物1を混合し、圧力
110atm、温度40℃で30分接触させ、重力沈降
槽5で軽液と重液に分離し、前記と同一の方法で処理し
た。Next, the entire amount of the light liquid and the raw material mixture 1 mentioned above were mixed and brought into contact at a pressure of 110 atm and a temperature of 40° C. for 30 minutes, separated into a light liquid and a heavy liquid in a gravity settling tank 5, and the same method as above was carried out. Processed.
その結果、ライン11よりco、以外の組成としてエタ
ノール85%、水17%、04〜Os系7−ゼル油検出
限界以下の濃縮精製されたエタノールが回収された。As a result, concentrated and purified ethanol with a composition other than co such as 85% ethanol, 17% water, and below the detection limit of 04-Os type 7-zel oil was recovered from line 11.
又、ライン18からはエタノールが実質的に含まれない
重液が取)出された。Also, a heavy liquid substantially free of ethanol was taken out from line 18.
この結果、原料混合物中のエタノールのはy全量が回収
されたことが明らかである。As a result, it is clear that the entire amount of ethanol in the raw material mixture was recovered.
実施例2
エタノール10 wt%、04〜C6系フーゼル油I]
、1 vt%、馬089.9 wt%の原料混合物1重
量部に、溶解溶剤としてCO,を6重量部加え、圧力1
10atm、温度20℃の擬臨界状態で30分接触させ
、重力沈降槽5で軽液と重液に分離した。Example 2 Ethanol 10 wt%, 04-C6 fusel oil I]
, 1 vt%, 089.9 wt% of the raw material mixture was added 6 parts by weight of CO as a dissolving solvent, and the pressure was 1.
The mixture was brought into contact for 30 minutes in a quasi-critical state at 10 atm and a temperature of 20° C., and separated into a light liquid and a heavy liquid in a gravity settling tank 5.
次に、軽液を重力沈降槽5上部より抜き出し、不純物分
離槽9に導入し、温度を40℃まで加熱し、圧力を11
0 atmから80 atmに減圧し、C,〜ち系フー
ゼル油と水及びエタノールを含む不純物混合物が相分離
槽9上部より取シ出された。相分離槽内残存物を分析し
たところ、002以外の組成はエタノール80%、水2
0%、C。Next, the light liquid is extracted from the upper part of the gravity settling tank 5 and introduced into the impurity separation tank 9, where the temperature is heated to 40°C and the pressure is increased to 11°C.
The pressure was reduced from 0 atm to 80 atm, and an impurity mixture containing C, - C fusel oil, water, and ethanol was taken out from the upper part of the phase separation tank 9. Analysis of the residue in the phase separation tank revealed that the composition other than 002 was 80% ethanol and 22% water.
0%, C.
〜へ系フーゼル油検出限界以下であシ、エタノールが濃
縮された。The ethanol concentration was below the detection limit for fusel oil.
次に、前記不純物混合物と重液を混合し、該混合物1重
量部に、溶解溶剤としてaO,を6重量部加え、圧力9
0 atm 、温度40℃で接触させ重力沈降槽17で
軽液と重液に分離した。Next, the impurity mixture and heavy liquid were mixed, 6 parts by weight of aO, as a dissolving solvent was added to 1 part by weight of the mixture, and the pressure was 9
They were brought into contact at 0 atm and a temperature of 40° C. and separated into a light liquid and a heavy liquid in a gravity settling tank 17.
次に、との軽液全量と首記原料混合物1を混合し、圧力
110atm、温度40℃で30分接触させ、重力沈降
槽5で軽液と重液に分離し、前記と同一の方法で処理し
た。Next, the entire amount of the light liquid and the raw material mixture 1 mentioned above were mixed and brought into contact at a pressure of 110 atm and a temperature of 40° C. for 30 minutes, separated into a light liquid and a heavy liquid in a gravity settling tank 5, and the same method as above was carried out. Processed.
その結果、ライン11よ6 co、以外の組成としてエ
タノール84%、水16%、04〜へ系7−ゼル油検出
限界以下の濃縮精製されたエタノールが回収された。As a result, concentrated and purified ethanol with a composition other than lines 11 to 6co, consisting of 84% ethanol, 16% water, and below the detection limit of 7-zel oil in lines 04 to 6co, was recovered.
又、ライン18からはエタノールが実質的に含まれない
重液が取シ出された。Also, a heavy liquid substantially free of ethanol was taken out from line 18.
この結果、原料混合物中のエタノールのはソ全量が回収
されたことが明らかである。As a result, it is clear that the entire amount of ethanol in the raw material mixture was recovered.
本発明は、以上詳記したよう忙アルコール、水、高沸点
不純物の混合物を、臨界付近の溶解溶剤を使用し常温付
近で圧力を2段階に制御して、これらの混合物を分離す
るものであシ、分離速度が早く装置のコンパクト化が可
能となるとともに、熱的負荷が軽減される省エネルギー
効果を生ずるものである。The present invention, as detailed above, separates a mixture of alcohol, water, and high-boiling point impurities by controlling the pressure in two stages at around room temperature using a near-critical dissolving solvent. Furthermore, the separation speed is high, the apparatus can be made compact, and the thermal load is reduced, resulting in an energy-saving effect.
第1図は、本発明を実施するだめのフローシートである
。
復代理人 内 1) 明
復代理人 萩 原 亮 −
復代理人 安 西 篤 夫FIG. 1 is a flow sheet for implementing the present invention. Sub-Agents 1) Meifuku Agent Ryo Hagiwara − Sub-Agent Atsuo Anzai
Claims (1)
とよりなる混合物に、溶解溶剤を加え、該溶解溶剤の超
臨界状態又は擬臨界状態になる条件で接触させて混合物
を形成させ、該混合物を第1抽出分離槽に導いて、水を
主成分とし大部分の高沸点不純物、一部のアルコール、
溶解溶剤を含有する重液と、溶解溶剤を主成分とし大部
分のアルコール、一部の高沸点不純物を含有する軽液に
分離させ、該軽液を該第1抽出分離槽より抜出して不純
物分離槽に導き、該不純物分離槽を減圧させることによ
り実質的に高沸点不純物を含まず水分が除去されたアル
コールと実質的に水と高沸点不純物と少量のアルコール
を含有する液とに分離し、前者を濃縮精製アルコールと
して回収し、後者を前記第1抽出分離槽からの重液と混
合し、該混合液に再度前記溶解溶剤を超臨界状態又は擬
臨界状態になる条件で接触させて混合物を形成させ、該
混合物を第2抽出分離槽で実質的に水と高沸点不純物よ
りなる重液と実質的に溶解溶剤とアルコールよりなる軽
液に分離し、後者の軽液を前記第1抽出分離槽に循環さ
せることを特徴とするアルコール濃縮精製方法。A dissolving solvent is added to a mixture consisting of alcohol, an organic liquid solute consisting of a high-boiling point impurity, and water, and the dissolving solvent is brought into contact with the mixture in a supercritical or quasi-critical state to form a mixture. 1. The main component is water, most of the high boiling point impurities, some alcohol,
Separate into a heavy liquid containing the dissolving solvent and a light liquid containing the dissolving solvent as the main component, most of the alcohol, and some high-boiling point impurities, and extract the light liquid from the first extraction separation tank to separate impurities. The alcohol is introduced into a tank, and the impurity separation tank is depressurized to separate alcohol from which water is removed and which does not substantially contain high-boiling impurities, and a liquid containing substantially water, high-boiling impurities, and a small amount of alcohol; The former is recovered as concentrated purified alcohol, the latter is mixed with the heavy liquid from the first extraction and separation tank, and the dissolving solvent is brought into contact with the mixed liquid again under conditions to reach a supercritical state or a quasi-critical state to form a mixture. The mixture is separated into a heavy liquid consisting essentially of water and high-boiling point impurities and a light liquid consisting essentially of a dissolving solvent and alcohol in a second extraction separation tank, and the latter light liquid is subjected to the first extraction separation. An alcohol concentration and purification method characterized by circulation in a tank.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP60165978A JPS6225984A (en) | 1985-07-29 | 1985-07-29 | Method of concentrating and purifying alcohol |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP60165978A JPS6225984A (en) | 1985-07-29 | 1985-07-29 | Method of concentrating and purifying alcohol |
Publications (1)
Publication Number | Publication Date |
---|---|
JPS6225984A true JPS6225984A (en) | 1987-02-03 |
Family
ID=15822606
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
JP60165978A Pending JPS6225984A (en) | 1985-07-29 | 1985-07-29 | Method of concentrating and purifying alcohol |
Country Status (1)
Country | Link |
---|---|
JP (1) | JPS6225984A (en) |
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPH0249741A (en) * | 1988-08-12 | 1990-02-20 | Tsuushiyousangiyoushiyou Kiso Sangiyoukiyokuchiyou | Method for purifying and concentrating aqueous solution of crude ethanol |
JPH041147A (en) * | 1990-04-16 | 1992-01-06 | Tsusho Sangyosho Kiso Sangyokyokucho | Separation of impurities in aqueous solution of crude ethanol |
WO1992021638A1 (en) * | 1991-06-07 | 1992-12-10 | Japan As Represented By Director-General, Basic Industries Bureau Of Ministry Of International Trade And Industry | Process for purifying aqueous crude ethanol solution |
US5763693A (en) * | 1995-02-24 | 1998-06-09 | Mitsui Chemicals, Inc. | Process for producing isopropyl alcohol |
-
1985
- 1985-07-29 JP JP60165978A patent/JPS6225984A/en active Pending
Cited By (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPH0249741A (en) * | 1988-08-12 | 1990-02-20 | Tsuushiyousangiyoushiyou Kiso Sangiyoukiyokuchiyou | Method for purifying and concentrating aqueous solution of crude ethanol |
JPH0512332B2 (en) * | 1988-08-12 | 1993-02-17 | Tsusho Sangyosho Kiso Sangyo Kyokucho | |
JPH041147A (en) * | 1990-04-16 | 1992-01-06 | Tsusho Sangyosho Kiso Sangyokyokucho | Separation of impurities in aqueous solution of crude ethanol |
WO1992021638A1 (en) * | 1991-06-07 | 1992-12-10 | Japan As Represented By Director-General, Basic Industries Bureau Of Ministry Of International Trade And Industry | Process for purifying aqueous crude ethanol solution |
US5284983A (en) * | 1991-06-07 | 1994-02-08 | Basic Industries Bureau of Ministry of International Trade and Industry | Process for purifying aqueous crude ethanol solution |
US5763693A (en) * | 1995-02-24 | 1998-06-09 | Mitsui Chemicals, Inc. | Process for producing isopropyl alcohol |
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