WO2014023136A1 - 一种低浓度有机溶剂水溶液回收热泵精馏装置及工艺 - Google Patents

一种低浓度有机溶剂水溶液回收热泵精馏装置及工艺 Download PDF

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Publication number
WO2014023136A1
WO2014023136A1 PCT/CN2013/077855 CN2013077855W WO2014023136A1 WO 2014023136 A1 WO2014023136 A1 WO 2014023136A1 CN 2013077855 W CN2013077855 W CN 2013077855W WO 2014023136 A1 WO2014023136 A1 WO 2014023136A1
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Prior art keywords
stripper
feed
reboiler
column
organic solvent
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PCT/CN2013/077855
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English (en)
French (fr)
Inventor
许松伟
于星
沈贵文
陆庆权
张�杰
崔磊
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南通醋酸纤维有限公司
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Publication of WO2014023136A1 publication Critical patent/WO2014023136A1/zh

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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01DSEPARATION
    • B01D3/00Distillation or related exchange processes in which liquids are contacted with gaseous media, e.g. stripping
    • B01D3/007Energy recuperation; Heat pumps
    • YGENERAL 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
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B30/00Energy efficient heating, ventilation or air conditioning [HVAC]
    • Y02B30/52Heat recovery pumps, i.e. heat pump based systems or units able to transfer the thermal energy from one area of the premises or part of the facilities to a different one, improving the overall efficiency

Definitions

  • the invention belongs to the field of chemical separation process and energy-saving technology, and relates to a low-concentration organic solvent aqueous solution recovery heat pump rectification device and a process. Background technique
  • Heat pump technology is a new energy technology that has received worldwide attention in recent years.
  • a heat pump is a device that transfers thermal energy from a low temperature heat source to a high temperature heat source.
  • heat pump technology is gradually used in the field of chemical rectification.
  • Supranto S. et al. studied the use of two-stage vapor compression, and the use of heat pump distillation in the rectification apparatus for separating ethanol and water (Heat pump assisted distillation. IX: Acceptance trails on a system for separating ethanol and water, International Journal Of Energy Research, 1988, 12, p413-422). Gaspillo P. et al.
  • Chinese patent 200810231613.0 introduces a diethyl carbonate heat pump rectification device and a process, and introduces the steam material at the top of the rectification column into a compressor to be used as a heat source for the refiller of the column.
  • Deng Renjie et al. studied the new process of butyl acetate heat pump distillation (Chemical Engineering, 2006, issue 6). In view of the high energy consumption of the conventional butyl acetate production process, it is proposed to apply heat pump distillation to the production of butyl acetate to develop acetic acid.
  • New process for butyl ester heat pump distillation The process also compresses the vapor at the top of the column and uses it for the heat source of the column reboiler.
  • the temperature difference between the column of the esterification column and the distillation column in the apparatus is 13 °C and 18 °C, respectively.
  • the object of the present invention is to provide a low concentration organic solvent-aqueous solution recovery heat pump rectification device and process.
  • the invention provides a low concentration organic solvent aqueous solution recovery heat pump rectification device, which comprises a feed preheater, a stripper, a compressor, a stripper reboiler and a rectification column; a feed preheater,
  • the stripper, compressor, stripper reboiler and rectification column are connected in series through the pipeline.
  • the feed preheater is provided with a feed preheater feed port, a feed preheater discharge port, a feed preheater heating medium feed port, and a feed preheater heating medium discharge port.
  • the feed medium of the feed preheater heating medium is located at the side of the feed preheater, and the feed medium of the feed preheater is located at the other side corresponding to the feed port of the feed medium of the feed preheater;
  • the feed preheater discharge port is connected with the stripper liquid feed inlet, the feed preheater heating medium feed port is connected with the stripper reboiler bottom discharge port, and the feed preheater heating medium is connected.
  • the discharge port is located at the lower portion of the feed preheater feed port.
  • the stripping tower is provided with a stripper liquid phase feed port, a stripping tower top end production outlet, a stripping column reboiling steam inlet, a stripping tower column kettle outlet, and a stripping tower tower kettle heating steam replenishing port.
  • the liquid phase feed inlet of the stripper is located at the upper middle of the side of the stripper, and the reboiling steam inlet of the stripper is located at the middle and lower side of the other side corresponding to the feed port of the heating medium of the stripping tower, the top of the stripping tower
  • the production outlet is located at the top of the stripping tower, and the outlet of the stripping tower is located at the bottom of the stripping tower; the heating medium feed port of the stripping tower is connected with the discharge port of the feed preheater, and the top outlet of the stripping tower is compressed and compressed.
  • the feed inlet of the machine is connected, the reboiling steam inlet of the stripping tower is connected with the outlet port of the reboiler reboiler, the outlet of the stripping tower is connected with the inlet of the stripper reboiler, and the stripping tower is heated.
  • the heated steam replenishing port is located in the stripper tower and is connected to an external heated steam supply line.
  • the compressor is provided with a compressor feed port and a compressor discharge port; the compressor feed port is connected with the top end of the stripper tower, and the compressor discharge port and the stripper reboiler heat exchange medium are introduced. Feed port connection.
  • the stripper reboiler is provided with a stripper reboiler top discharge port, a stripper reboiler heat exchange medium feed port, a stripper reboiler feed port, a stripper The reboiler bottom outlet and the stripper reboiler heat exchange medium outlet, the stripper reboiler top outlet is located at the top of the stripper reboiler, the stripper reboiler tower
  • the bottom discharge port is located at the bottom of the stripper reboiler, the stripper reboiler feed port is located on the side of the stripper reboiler, the stripper reboiler heat exchange medium feed port and the stripper
  • the reboiler heat exchange medium discharge port is located at the upper and lower sides of the other side of the stripper reboiler feed port; the stripper reboiler column top discharge port and the stripper reboiled steam inlet Connection, stripper
  • the rectification column is provided with a distillation column overhead production outlet, a distillation column tower kettle production outlet and a rectification column feed port, and the distillation column top mining outlet is located at the top of the rectification column, and the distillation tower is
  • the kettle extraction outlet is located at the bottom of the rectification column, and the rectification column feed port is located at the side of the rectification column; the rectification column feed port is connected with the stripper deoiler heat exchange medium discharge port.
  • the invention also provides a low-concentration organic solvent aqueous solution recovery heat pump rectification process, the process comprising the following steps: First, an aqueous solution containing a low concentration organic solvent is introduced into a feed preheater to be heated to a bubble point, and subjected to stripping In the tower After stripping treatment, the material steam from the top of the stripper is passed to a compressor for compression, and then introduced into a stripper reboiler as a heat source of the stripper reboiler for heat exchange, and finally, stripping The condensed material from the column reboiler is treated as a rectification column feed for the rectification process, and a high concentration organic solvent is produced at the top of the rectification column.
  • the organic solvent is one or more organic compounds capable of being miscible with water.
  • the organic compound of the ⁇ is selected from the group consisting of an alcohol, a ketone, an aldehyde or an ester organic compound, such as: methanol, ethanol, n-propanol, isopropanol, formaldehyde, acetaldehyde, propionaldehyde, acetone, methyl ethyl ketone, methyl formate or Ethyl formate.
  • the low concentration organic solvent refers to a mass concentration of the organic solvent in water of 3 to 20%.
  • the feed preheater and the stripper reboiler are selected from the group consisting of a plate heat exchanger, a tube heat exchanger, a tube plate heat exchanger or a spiral plate heat exchanger, and the heat exchange temperature difference ranges from 10 ⁇ 60 ° C.
  • the compressor is selected from the group consisting of a volumetric compressor, a reciprocating compressor, and a centrifugal compressor, and has a temperature rising range of 20-60 ° C and a compression ratio of 1.5 to 4.0.
  • the rectification column is selected from the group consisting of a sieve tray tower, a float valve tower or a packed tower, and the temperature difference between the top of the distillation column and the tower kettle is 20 to 45 °C.
  • the present invention has the following advantages and beneficial effects:
  • the invention can be widely applied to the separation of various organic compound materials.
  • the invention can effectively reduce the chemical rectification process, especially the energy consumption of the rectification process using heat pump technology, and reduce the production cost.
  • Figure 1 shows a heat pump rectification process diagram using a dilute solution.
  • 1 is the feed preheater
  • 2 is the stripper
  • 3 is the compressor
  • 4 is the stripper reboiler
  • 5 is the rectification tower
  • 11 is the feed preheater feed port
  • 12 is the feed Feeder preheater discharge port
  • 13 is feed preheater heating medium feed port
  • 14 is feed preheater heating medium discharge port
  • 21 is stripper liquid phase feed port
  • 22 is stripper
  • the top of the tower is the outlet
  • 23 is the stripping tower reboiling steam inlet
  • 24 is the stripping tower tray outlet
  • 25 is the stripping tower tower heating steam replenishing port
  • 31 is the compressor inlet
  • 32 is the compressor
  • the discharge port, 41 is the stripper reboiler top discharge port
  • 42 is the stripper reboiler heat exchange medium feed port
  • 43 is the stripper reboiler feed port
  • 44 is the stripper
  • 45 is the stripper
  • Figure 2 shows a diagram of a conventional rectification process using a dilute solution.
  • 6 is the feed preheater
  • 7 is the rectification column
  • 61 is the feed preheater feed port
  • 62 is the feed preheater discharge port
  • 63 is the feed preheater heating medium feed port
  • 64 is the feed preheater heating medium discharge port
  • 71 is the rectification tower tower top production outlet
  • 72 is the rectification tower tower kettle recovery outlet
  • 73 is the rectification column feed port.
  • all percentages (%) are the mass percentage of a component in a system, for example, the mass percentage of the solute in the solution; all "in-range" include the terminal value,
  • the organic solvent includes 1% and 10% in a mass concentration range of 1% to 10% in water.
  • the concentration is 3.5%% of the diluted acetone solution
  • the flow rate is 140T/h
  • the compressor compression ratio is 3.0
  • the temperature difference of the distillation tower 7 tower top is 45 °C.
  • the feed temperature is 50 ° C
  • the heat is exchanged between the feed preheater 1 and the stripper reboiler 4 column to 97 ° C, then enters the stripper 2 from the top, strips the acetone, and ensures the tower
  • the acetone content of the kettle is less than 100 ppm.
  • acetone water vapor of 90 ° C or higher and acetone mass content of about 50% is produced, and the steam is heated and compressed by the compressor 3 to be heat-exchanged as a heat source of the stripper reboiler 4 .
  • the acetone vapor is partially condensed while heat exchange in the stripper reboiler 4, and the condensed material enters the rectification column 5 to separate the acetone and the water, ensuring that the acetone concentration at the top is greater than 98.5 wt%, and the acetone concentration in the column is less than 100 ppm.
  • the heat pump rectification process is adopted to ensure that the acetone concentration of the column top product of the rectification column 5 reaches 98.5 wt.%, and the acetone concentration of the column reactor is less than 100 ppm, the stripping tower 2 needs to pass the heating steam heat to 1.89 Gcal/h, and the rectification Tower 5 has a reboiling heat of 0.42 Gcal/h and a total calorific value of 2.31 Gcal/h. There is no condensation or cooler at the top of the stripper tower. The heat exchange capacity of the distillation tower at the top of the distillation tower is 1.35 Gcal/h. In addition, the power of the compressor 3 is 610 KW (0.44 GKal/h).
  • the concentration is 3.5%% of the dilute acetone solution
  • the flow rate is 140T/h
  • the compressor compression ratio is 3.0
  • the temperature difference of the distillation tower 7 tower top is 45 V.
  • the feed temperature was 50 ° C
  • the heat exchange rate between the feed preheater 6 and the rectification column 7 was increased to 97 ° C and then entered the rectification column 7.
  • the actual number of plates was 50.
  • the acetone concentration at the top of the rectification column 7 can reach 98.5 wt%, and the acetone concentration in the rectification column 7 is less than 100 ppm.
  • the reboiling energy consumption of the distillation column ⁇ tower is 4.40 Gcal/h
  • the cooling capacity required for condensing cooling of the distillation column 7 is 3.27 Gcal/h.
  • the methanol solution having a concentration of 5.0 wt% has a flow rate of 140 T/h, the compression ratio of the compressor is 2.0, and the temperature difference of the column top column of the rectification column 7 is 40 °C.
  • the feed preheater 1 and the stripper reboiler 4 tower kettle liquid heat exchange to 80 ° C then enter the stripper 2 from the top, stripping the methanol, and ensure The methanol content of the tower kettle is less than 100 ppm.
  • methanol-water vapor of 90 ° C or higher and methanol mass content of about 30% is produced, and the vapor is compressed and heated by the compressor 3 to be heated as a heat source of the stripper reboiler 4 exchange.
  • the heat pump rectification process is adopted to ensure that the methanol concentration of the column top product of the rectification column 5 reaches 98.5 wt%, and the methanol concentration of the column reactor is less than 100 ppm.
  • the stripper 2 needs to pass the heating steam heat to 2.16Gcal/h, the rectification tower 5 reboil heat is 3.35Gcal/h, and the total calorific value is 5.51Gcal/h.
  • the heat exchange capacity of the distillation tower at the top of the distillation tower is 3.47 Gcal/h.
  • the power of the compressor 3 is 705 KW (0.61 GKal/h).
  • the methanol solution having a concentration of 5.0 wt% has a flow rate of 140 T/h, the compression ratio of the compressor is 2.0, and the temperature difference of the top column of the rectification column 7 is 40 °C.
  • the feed temperature of 50 ° C after the feed preheater 6 and the rectification tower 7 tower liquid exchange heat exchange to 80 ° C, then enter the rectification tower 7, the actual number of trays is 60, dilute methanol ordinary distillation
  • the process is shown in Figure 2.
  • the reflux ratio is 1.6
  • the methanol concentration at the top of the rectification column 7 can reach 98.5 wt%, and the methanol concentration in the rectification column 7 column is less than 100 ppm.
  • the reboiling energy consumption of the rectification tower 7 tower is 11.08 Gcal/h
  • the cooling capacity required for the condensing cooling of the rectification tower 7 is 8.55 Gcal/h.
  • the heat pump distillation process reduced the total heat consumption by 5.57 Gcal/h, and the circulating cooling consumption was reduced by 5.08 Gcal/h, which only increased the power consumption, and the total energy saving was 10.04 Gcal/h.
  • the methanol solution having a concentration of 20.0 wt% has a flow rate of 140 T/h, a compression ratio of the compressor of 1.5, and a temperature difference of the top column of the rectification column 7 of 30 °C.
  • the feed preheater 1 and the stripper reboiler 4 tower kettle liquid heat exchange to 80 ° C then enter the stripper 2 from the top, stripping the methanol, and ensure The methanol content of the tower kettle is less than 100 ppm.
  • methanol-water vapor of 90 ° C or higher and methanol mass content of about 60% is produced, and the vapor is compressed and heated by the compressor 3 to be heated as a heat source of the stripper reboiler 4 exchange.
  • Methanol-water vapor is partially condensed while heat exchange in the stripper reboiler 4, and the condensed material enters the rectification column 5 to separate methanol and water, ensuring that the methanol concentration at the top of the column is greater than 95 wt%, and the distillation column is 5 towers.
  • the methanol concentration is less than 100 ppm. Since the latent heat of condensation of methanol-steam can not meet the demand of the stripper reboiler 4, it is necessary to introduce a portion of the heated steam in the stripper 2 to provide energy.
  • the heat pump rectification process is adopted to ensure that the methanol concentration of the column top product of the rectification column 5 reaches 95 wt%, and the methanol concentration of the column reactor is less than 100 ppm.
  • the stripper 2 needs to pass the heating steam heat of 2.54Gcal/h, the rectification tower 5 reboil heat is 6.41Gcal/h, and the total calorific value is 8.95Gcal/h. There is no condensation or cooler at the top of the stripping tower.
  • the heat exchange capacity of the distillation tower at the top of the distillation tower is 9.68 Gcal/h.
  • the power of the compressor 3 is 443 KW (0.38 Gcal/h).
  • the methanol solution having a concentration of 20.0 wt% has a flow rate of 140 T/h, a compression ratio of the compressor of 1.5, and a temperature difference of the top column of the rectification column 7 of 30 °C.
  • the feed temperature of 50 ° C after the feed preheater 6 and the rectification tower 7 tower liquid exchange heat exchange to 80 ° C, then enter the rectification column 7, the actual number of plates is 45, dilute methanol common rectification
  • the process is shown in Figure 2.
  • the reflux ratio is 2.5
  • the methanol concentration at the top of the rectification column 7 can reach 95 wt%, and the methanol concentration in the rectification column 7 is less than 100 ppm.
  • Example 3 Using ordinary distillation process, fine The reboiling energy consumption of the column 7 column was 33.7 Gcal/h, and the cooling capacity required for the condensing cooling of the column 7 of the distillation column was 30.6 Gcal/h.
  • the heat pump distillation process reduced the total heat consumption by 24.75 G C a /h, reduced the circulating cooling consumption by 20.92 Gcal/h, and increased the power consumption by 0.38 Gcal/h. 45.29Gcal/h.
  • Fig. 1 shows a heat pump rectification process diagram using a dilute solution.
  • a low-concentration organic solvent aqueous solution recovery heat pump rectification device the device comprises a feed preheater 1, a stripper 2, a compressor 3, a stripper reboiler 4 and a rectification column 5; a feed preheater 1.
  • the stripper 2, the compressor 3, the stripper reboiler 4, and the rectification column 5 are sequentially connected through a pipeline.
  • the feed preheater 1 is provided with a feed preheater feed port 11, a feed preheater discharge port 12, a feed preheater heating medium feed port 13 and a feed preheater heating medium discharge Port 14, feed preheater heating medium feed port 13 is located on the side of the feed preheater 1, feed preheater heating medium discharge port 14 is located in the feed preheater heating medium feed port 13 corresponding to The other side of the feed preheater outlet 12 is connected to the stripper liquid feed inlet 21, the feed preheater heating medium feed port 13 and the stripper reboiler bottom discharge port 44 Connection, Feed Preheater The heating medium discharge port 14 is located at the lower portion of the feed preheater feed port 11.
  • the stripper 2 is provided with a stripper liquid phase feed port 21, a stripper column top outlet 22, a stripper reboil inlet 23, a stripper column outlet 24 and a stripper column.
  • Heating the steam replenishing port 25, the stripper liquid phase feed port 21 is located at the upper middle side of the stripping column 2, and the stripping column reboiling steam inlet 23 is located at the other side corresponding to the stripping tower heating medium feed port 21
  • the top extraction outlet 22 of the stripper is located at the top of the stripping tower 2, and the stripping port 24 of the stripping tower is located at the bottom of the stripping tower 2; the stripping tower heating medium inlet 21 and the feed pre-feed
  • the heater outlet 12 is connected, the stripper top outlet 22 is connected to the compressor inlet 31, the stripper reboiled steam inlet 23 is connected to the stripper reboiler top outlet 41, and stripping
  • the Tata kettle discharge port 24 is connected to the stripper reboiler feed port 43.
  • the compressor 3 is provided with a compressor feed port 31 and a compressor discharge port 32; the compressor feed port 31 is connected with the stripper tower top outlet port 22, the compressor discharge port 32 and the stripper reboiler
  • the heat exchange medium feed port 42 is connected.
  • the stripper reboiler 4 is provided with a stripper reboiler overhead discharge port 41, a stripper reboiler heat exchange medium feed port 42, a stripper reboiler feed port 43, and stripping Tower reboiler bottom outlet 44 and stripper reboiler heat exchange medium outlet 45, stripper reboiler overhead outlet 41 is located at the top of stripper reboiler 4, stripping The bottom of the column reboiler bottom outlet 44 is located at the bottom of the stripper reboiler 4, and the stripper reboiler feed port 43 is located on the side of the stripper reboiler 4, and the stripper is replaced by a reboiler.
  • the heat medium feed port 42 and the stripper reboiler heat exchange medium discharge port 45 are located at the upper and lower portions of the other side corresponding to the stripper reboiler feed port 43; the stripper reboiler tower
  • the top discharge port 41 is connected to the stripper reflux steam inlet 23
  • the stripper reboiler heat exchange medium feed port 42 is connected to the compressor discharge port 32
  • the stripper reboiler inlet 43 is connected with the steam.
  • the Tata tower kettle outlet 24 is connected, the stripper reboiler bottom outlet port 44 is connected with the feed preheater heating medium inlet port 13, and the stripper reboiler heat exchange medium outlet port 45 is
  • the distillation column feed port 53 is connected.
  • the rectification column 5 is provided with a rectification tower overhead production outlet 51, a rectification tower tower cauterization outlet 52, and a rectification column feed port 53.
  • the rectification tower top extraction outlet 51 is located at the top of the rectification column 5
  • the distillation column tower recovery port 52 is located at the bottom of the rectification column 5
  • the rectification column feed port 53 is located at the side of the rectification column 5; the rectification column feed port 53 and the stripper deoiler heat exchange medium discharge Port 45 is connected.

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  • Chemical & Material Sciences (AREA)
  • Chemical Kinetics & Catalysis (AREA)
  • Vaporization, Distillation, Condensation, Sublimation, And Cold Traps (AREA)
  • Organic Low-Molecular-Weight Compounds And Preparation Thereof (AREA)

Abstract

一种低浓度有机溶剂水溶液回收热泵精馏装置及工艺,该装置包括进料预热器、汽提塔、压缩机、汽提塔再沸器和精馏塔,进料预热器、汽提塔、压缩机、汽提塔再沸器和精馏塔依次经过管路连接,其工艺步骤为:将含有低浓度有机溶剂的水溶液通入进料预热器中加热到泡点,通入汽提塔中进行提馏处理,将汽提塔塔顶采出蒸汽通入压缩机进行压缩后,通入汽提塔再沸器作为热源进行换热,从汽提塔再沸器出来的冷凝物料作为精馏塔进料进行精馏工艺处理,在精馏塔塔顶采出产品。

Description

一种低浓度有机溶剂水溶液回收热泵精馏装置及工艺 技术领域
本发明属于化工分离过程和节能技术领域, 涉及一种低浓度有机溶剂水溶液回收热泵精 馏装置及工艺。 背景技术
在化工生产过程中, 经常会产生大量含有低浓度有机溶剂的水溶液, 对水溶液中的有机 溶剂的回收, 目前大多采用精馏工艺处理。 但是, 由于水溶液中的有机溶剂的浓度较低, 精 馏分离得到较纯的有机溶剂产品所需的精馏塔理论板数高, 回流比高, 能耗大。 如果采用首 先将稀溶液提浓然后精馏的工艺, 虽然精馏塔回流比降低, 但是先提浓再精馏整个工艺的能 耗比单独使用精馏工艺的能耗反而有所增加。
热泵技术是近年来在全世界倍受关注的新能源技术。 热泵是一种将低温热源的热能转移 到高温热源的装置。 作为一种余热利用的有效工具, 热泵技术逐渐运用在化工精馏领域。 Supranto S.等人研究了涉及两级蒸汽压缩, 在分离乙醇和水的精馏装置中采用了热泵精馏技 术 (Heat pump assisted distillation. IX: Acceptance trails on a system for separating ethanol and water, International Journal of Energy Research, 1988, 12, p413-422)。 Gaspillo P.等人介绍了 在脱氢异丙醇反应精馏塔采用化学热泵精馏技术 (Dehydrogenation of 2-propanol in reactive distillation column for chemical heat pump, Journal of Chemical Engineering of Japan, 1998, 31, p440-444)o 中国专利 200680023637.6介绍了一种使用热泵的精馏设备, 用于精馏含水混合物 中易汽化成分。
中国专利 200810231613.0介绍了碳酸二乙酯热泵精馏装置及工艺, 将精馏塔顶蒸汽物料 引入压缩机加压后用于塔釜再沸器热源。 邓仁杰等人研究醋酸丁酯热泵精馏新工艺 (化学工 程, 2006年 6期), 针对常规醋酸丁酯生产工艺能耗高的特点, 提出将热泵精馏应用于醋酸丁 酯生产, 开发出醋酸丁酯热泵精馏新工艺。 该工艺同样将塔顶蒸汽压缩后用于塔釜再沸器热 源, 装置中酯化塔和精馏塔的塔顶塔釜温差分别为 13 °C和 18°C。
将热泵技术应用于化工行业精馏工艺, 能够减少热能浪费, 降低部分能源消耗, 但上述 工艺不能应用于普遍存在的精馏塔塔顶塔釜之间温差较大的工况。 发明内容 为了将热泵技术运用于精馏塔塔顶塔釜之间温差较大的工况, 本发明的目的是提供一种 低浓度有机溶剂一水溶液回收热泵精馏装置及工艺。
本发明的技术方案如下:
本发明提供了一种低浓度有机溶剂水溶液回收热泵精馏装置, 该装置包括进料预热器、 汽提塔、 压缩机、 汽提塔再沸器和精馏塔; 进料预热器、 汽提塔、 压缩机、 汽提塔再沸器和 精馏塔依次经过管路连接。
所述的进料预热器上设有进料预热器进料口、 进料预热器出料口、 进料预热器加热介质 进料口和进料预热器加热介质出料口, 进料预热器加热介质进料口位于进料预热器的侧边, 进料预热器加热介质出料口位于进料预热器加热介质进料口相对应的另一侧边; 进料预热器 出料口与汽提塔液相进料口连接, 进料预热器加热介质进料口与汽提塔再沸器塔底出料口连 接, 进料预热器加热介质出料口位于进料预热器进料口的下部。
所述的汽提塔上设有汽提塔液相进料口、 汽提塔塔顶采出口、 汽提塔再沸蒸汽入口、 汽 提塔塔釜出口和汽提塔塔釜加热蒸汽补充口, 汽提塔液相进料口位于汽提塔的侧边中上部, 汽提塔再沸蒸汽入口位于汽提塔加热介质进料口相对应的另一侧边中下部, 汽提塔塔顶采出 口位于汽提塔的顶部, 汽提塔塔釜出口位于汽提塔的底部; 汽提塔加热介质进料口与进料预 热器出料口连接, 汽提塔塔顶采出口与压缩机进料口连接, 汽提塔再沸蒸汽入口与汽提塔再 沸器塔顶出料口连接, 汽提塔塔釜出口与汽提塔再沸器进料口连接, 汽提塔塔釜加热蒸汽补 充口位于汽提塔塔釜, 与外部加热蒸汽供应管道连接。
所述的压缩机上设有压缩机进料口和压缩机出料口; 压缩机进料口与汽提塔塔顶采出口 连接, 压缩机出料口与汽提塔再沸器换热介质进料口连接。
所述的汽提塔再沸器上设有汽提塔再沸器塔顶出料口、 汽提塔再沸器换热介质进料口、 汽提塔再沸器进料口、 汽提塔再沸器塔底出料口和汽提塔再沸器换热介质出料口, 汽提塔再 沸器塔顶出料口位于汽提塔再沸器的顶部, 汽提塔再沸器塔底出料口位于汽提塔再沸器的底 部, 汽提塔再沸器进料口位于汽提塔再沸器的侧边, 汽提塔再沸器换热介质进料口和汽提塔 再沸器换热介质出料口位于汽提塔再沸器进料口相对应的另一侧边的上部和下部; 汽提塔再 沸器塔顶出料口与汽提塔再沸蒸汽入口连接, 汽提塔再沸器换热介质进料口与压缩机出料口 连接, 汽提塔再沸器进料口与汽提塔塔釜出口连接, 汽提塔再沸器塔底出料口与进料预热器 加热介质进料口连接, 汽提塔再沸器换热介质出料口与精馏塔进料口连接。
所述的精馏塔上设有精馏塔塔顶采出口、 精馏塔塔釜采出口和精馏塔进料口, 精馏塔塔 顶采出口位于精馏塔的顶部, 精馏塔塔釜采出口位于精馏塔的底部, 精馏塔进料口位于精馏 塔的侧边; 精馏塔进料口与汽提塔再沸器换热介质出料口连接。
本发明还提供了一种低浓度有机溶剂水溶液回收热泵精馏工艺, 该工艺包括以下步骤: 首先将含有低浓度有机溶剂的水溶液通入进料预热器中加热到泡点, 通入汽提塔中进行 提馏处理, 然后将汽提塔塔顶采出的物料蒸汽通入压缩机进行压缩后, 通入汽提塔再沸器作 为汽提塔再沸器的热源进行热换, 最后, 从汽提塔再沸器出来的冷凝物料作为精馏塔进料进 行精馏工艺处理, 在精馏塔塔顶采出高浓度有机溶剂。
所述的有机溶剂为能够与水互溶的一种或一种以上 ^〜 的有机化合物。
所述的 〜 的有机化合物选自醇、 酮、 醛或酯类有机化合物, 例如: 甲醇、 乙醇、 正 丙醇、 异丙醇、 甲醛、 乙醛、 丙醛、 丙酮、 甲乙酮、 甲酸甲酯或甲酸乙酯。
所述的低浓度有机溶剂是指有机溶剂在水中的质量浓度为 3~20%。
所述的进料预热器、 汽提塔再沸器选自板式换热器、 管式换热器、 管板式换热器或者螺 旋板式换热器中的一种, 换热温差范围在 10~60°C。
所述的压缩机选自容积式压缩机, 往复式压缩机, 离心式压缩机中的一种, 升温范围在 20-60 °C , 压缩比为 1.5~4.0。
所述的精馏塔选自筛板塔, 浮阀塔或者填料塔中的一种, 精馏塔的塔顶和塔釜的温差范 围为 20~45 °C。
本发明同现有技术相比, 具有如下优点和有益效果:
1、 本发明可广泛运用于各类有机化合物物料分离。
2、 本发明能够有效地降低化工精馏过程, 特别是采用热泵技术的精馏过程的能源消耗, 降低生产成本。 附图说明
图 1 表示采用稀溶液的热泵精馏工艺图。
其中: 1为进料预热器、 2为汽提塔、 3为压缩机、 4为汽提塔再沸器、 5为精馏塔、 11 为进料预热器进料口、 12为进料预热器出料口、 13为进料预热器加热介质进料口、 14为进 料预热器加热介质出料口、 21 为汽提塔液相进料口、 22为汽提塔塔顶采出口、 23为汽提塔 再沸蒸汽入口、 24为汽提塔塔釜出料口、 25为汽提塔塔釜加热蒸汽补充口、 31 为压缩机进 料口、 32为压缩机出料口、 41 为汽提塔再沸器塔顶出料口、 42为汽提塔再沸器换热介质进 料口、 43为汽提塔再沸器进料口、 44为汽提塔再沸器塔底出料口、 45为汽提塔再沸器换热 介质出料口、 51为精馏塔塔顶采出口、 52为精馏塔塔釜采出口、 53为精馏塔进料口。
图 2 表示采用稀溶液的普通精馏工艺图。
其中: 6为进料预热器、 7为精馏塔、 61为进料预热器进料口、 62为进料预热器出料口、 63为进料预热器加热介质进料口、 64为进料预热器加热介质出料口、 71 为精馏塔塔顶采出 口、 72为精馏塔塔釜采出口、 73为精馏塔进料口。 具体实施方式 以下结合附图所示实施例对本发明作进一步的说明。
本发明中, 除非另有定义, 所有的百分比 (%) 均为某一成分在某一体系中的质量百分 比, 例如, 溶质在溶液中的质量百分比; 所有的 "范围内"均包括端值, 例如, 有机溶剂在 水中的质量浓度为 1%-10%范围内包括 1%和 10%。
实施例 1
采用热泵精馏工艺分离稀丙酮溶液的工艺流程如图 1所示。
浓度为 3.5^%的稀丙酮溶液, 流量为 140T/h, 压缩机压缩比为 3.0, 精馏塔 7塔顶塔釜 温差为 45°C。 进料温度为 50°C, 经进料预热器 1与汽提塔再沸器 4塔釜液换热至 97°C后从 顶部进入汽提塔 2, 汽提其中的丙酮, 并保证塔釜采出的丙酮含量小于 100ppm。 汽提塔 2塔 顶采出 90°C以上、 丙酮质量含量约为 50%左右的丙酮水蒸汽, 将该蒸汽通过压缩机 3压缩升 温后, 作为汽提塔再沸器 4的热源进行热交换。 丙酮水蒸汽在汽提塔再沸器 4中换热的同时 发生部分冷凝,冷凝物料进入精馏塔 5实现丙酮和水的分离,保证塔顶丙酮浓度大于 98.5wt%, 塔釜丙酮浓度小于 100ppm。由于仅靠丙酮水蒸汽的冷凝潜热并不能满足汽提塔再沸器 4的需 求, 因此需要在汽提塔 2中通入部分加热蒸汽以提供能量。
采用热泵精馏工艺, 在保证精馏塔 5塔顶产品丙酮浓度达到 98.5wt.%, 塔釜丙酮浓度小 于 lOOppm条件下,汽提塔 2需要通入加热蒸汽热量为 1.89 Gcal/h,精馏塔 5再沸热量为 0.42 Gcal/h, 合计消耗热量为 2.31Gcal/h。 汽提塔 2塔顶不设冷凝、 冷却器, 精馏塔 5塔顶冷凝冷 却器的换热量为 1.35 Gcal/h。 另夕卜, 压缩机 3的功率为 610KW (0.44 GKal/h)。
比较例 1
3.5^%的稀丙酮溶液普通精馏工艺流程如图 2所示。
浓度为 3.5^%的稀丙酮溶液, 流量为 140T/h, 压缩机压缩比为 3.0, 精馏塔 7塔顶塔釜 温差为 45 V。 进料温度为 50°C, 经过进料预热器 6与精馏塔 7塔釜液换热至 97°C后进入精 馏塔 7, 实际塔板数为 50块。 在回流比为 3.8时, 精馏塔 7塔顶丙酮浓度才能达到 98.5wt%, 精馏塔 7 塔釜丙酮浓度小于 100ppm。 采用普通精馏工艺, 精馏塔 Ί 塔釜再沸能耗达到 4.40Gcal/h, 精馏塔 7塔顶冷凝冷却需要的冷量为 3.27Gcal/h。
实施例 1与比较例 1相比, 采用热泵精馏工艺, 总的热量消耗降低 2.09GCal/h, 循环冷 却量消耗降低 1.92Gcal/h, 仅增加电耗 0.44Gcal/h, 合计节约能量 3.57Gcal/h。
实施例 2
浓度为 5.0wt%的甲醇溶液, 流量为 140T/h, 压缩机压缩比为 2.0, 精馏塔 7塔顶塔釜温 差为 40°C。 按进料温度为 50°C, 经进料预热器 1与汽提塔再沸器 4塔釜液换热至 80°C后从 顶部进入汽提塔 2, 汽提其中的甲醇, 并保证塔釜采出的甲醇含量小于 100ppm。 汽提塔 2塔 顶采出 90°C以上、 甲醇质量含量约为 30%左右的甲醇一水蒸汽, 将该汽体通过压缩机 3压缩 升温后, 作为汽提塔再沸器 4热源进行热交换。 甲醇一水蒸汽在汽提塔再沸器 4中换热的同 时发生部分冷凝, 冷凝物料进入精馏塔 5 实现甲醇和水的分离, 保证塔顶甲醇浓度大于 98.5wt%, 精馏塔 5塔釜甲醇浓度小于 100ppm。 由于甲醇一水蒸汽的冷凝潜热并不能满足汽 提塔再沸器 4的需求, 因此需要在汽提塔 2塔釜中通入部分加热蒸汽以提供能量。
采用热泵精馏工艺, 在保证精馏塔 5塔顶产品甲醇浓度达到 98.5wt%, 塔釜甲醇浓度小 于 lOOppm条件下。 汽提塔 2 需要通入加热蒸汽热量为 2.16Gcal/h, 精馏塔 5 再沸热量为 3.35Gcal/h, 合计消耗热量为 5.51Gcal/h。 汽提塔 2塔顶不设冷凝、 冷却器, 精馏塔 5塔顶冷 凝冷却器的换热量为 3.47Gcal/h。 另夕卜, 压缩机 3的功率为 705KW ( 0.61GKal/h)。
比较例 2
浓度为 5.0wt%的甲醇溶液, 流量为 140T/h, 压缩机压缩比为 2.0, 精馏塔 7塔顶塔釜温 差为 40°C。 按进料温度为 50°C, 经过进料预热器 6与精馏塔 7塔釜液换热至 80°C后进入精 馏塔 7, 实际塔板数为 60块, 稀甲醇普通精馏过程如图 2所示。 在回流比为 1.6时, 精馏塔 7塔顶甲醇浓度才能达到 98.5wt%,精馏塔 7塔釜甲醇浓度小于 100ppm。采用普通精馏工艺, 精馏塔 7塔釜再沸能耗达到 11.08Gcal/h, 精馏塔 7塔顶冷凝冷却需要的冷量为 8.55Gcal/h。
实施例 2与比较例 2相比, 采用热泵精馏工艺, 总的热量消耗降低 5.57Gcal/h, 循环冷 却量消耗降低 5.08Gcal/h, 仅增加电耗, 合计节约能量 10.04Gcal/h。
实施例 3
浓度为 20.0wt%的甲醇溶液, 流量为 140T/h, 压缩机压缩比为 1.5, 精馏塔 7塔顶塔釜温 差为 30°C。 按进料温度为 50°C, 经进料预热器 1与汽提塔再沸器 4塔釜液换热至 80°C后从 顶部进入汽提塔 2, 汽提其中的甲醇, 并保证塔釜采出的甲醇含量小于 100ppm。 汽提塔 2塔 顶采出 90°C以上、 甲醇质量含量约为 60%左右的甲醇一水蒸汽, 将该汽体通过压缩机 3压缩 升温后, 作为汽提塔再沸器 4热源进行热交换。 甲醇一水蒸汽在汽提塔再沸器 4中换热的同 时发生部分冷凝, 冷凝物料进入精馏塔 5 实现甲醇和水的分离, 保证塔顶甲醇浓度大于 95wt%, 精馏塔 5塔釜甲醇浓度小于 100ppm。 由于甲醇一水蒸汽的冷凝潜热并不能满足汽提 塔再沸器 4的需求, 因此需要在汽提塔 2塔釜中通入部分加热蒸汽以提供能量。
采用热泵精馏工艺, 在保证精馏塔 5塔顶产品甲醇浓度达到 95wt%, 塔釜甲醇浓度小于 lOOppm 条件下。 汽提塔 2 需要通入加热蒸汽热量为 2.54Gcal/h, 精馏塔 5 再沸热量为 6.41Gcal/h, 合计消耗热量为 8.95Gcal/h。 汽提塔 2塔顶不设冷凝、 冷却器, 精馏塔 5塔顶冷 凝冷却器的换热量为 9.68Gcal/h。 另夕卜, 压缩机 3的功率为 443KW ( 0.38Gcal/h)。
比较例 3
浓度为 20.0wt%的甲醇溶液, 流量为 140T/h, 压缩机压缩比为 1.5, 精馏塔 7塔顶塔釜温 差为 30°C。 按进料温度为 50°C, 经过进料预热器 6与精馏塔 7塔釜液换热至 80°C后进入精 馏塔 7, 实际塔板数为 45块, 稀甲醇普通精馏过程如图 2所示。 在回流比为 2.5时, 精馏塔 7塔顶甲醇浓度能达到 95wt%, 精馏塔 7塔釜甲醇浓度小于 100ppm。 采用普通精馏工艺, 精 馏塔 7塔釜再沸能耗达到 33.7Gcal/h, 精馏塔 7塔顶冷凝冷却需要的冷量为 30.6Gcal/h。 实施例 3与比较例 3相比, 采用热泵精馏工艺, 总的热量消耗降低 24.75GCal/h, 循环冷 却量消耗降低 20.92Gcal/h, 仅增加电耗 0.38Gcal/h, 合计节约能量 45.29Gcal/h。
实施例 4
如图 1所示, 图 1 表示采用稀溶液的热泵精馏工艺图。
一种低浓度有机溶剂水溶液回收热泵精馏装置, 该装置包括进料预热器 1、汽提塔 2、压 缩机 3、 汽提塔再沸器 4和精馏塔 5 ; 进料预热器 1、 汽提塔 2、 压缩机 3、 汽提塔再沸器 4 和精馏塔 5依次经过管路连接。
进料预热器 1上设有进料预热器进料口 11、进料预热器出料口 12、进料预热器加热介质 进料口 13和进料预热器加热介质出料口 14, 进料预热器加热介质进料口 13位于进料预热器 1的侧边, 进料预热器加热介质出料口 14位于进料预热器加热介质进料口 13相对应的另一 侧边; 进料预热器出料口 12与汽提塔液相进料口 21连接, 进料预热器加热介质进料口 13与 汽提塔再沸器塔底出料口 44连接, 进料预热器加热介质出料口 14位于进料预热器进料口 11 的下部。
汽提塔 2上设有汽提塔液相进料口 21、 汽提塔塔顶采出口 22、 汽提塔再沸蒸汽入口 23、 汽提塔塔釜出料口 24和汽提塔塔釜加热蒸汽补充口 25, 汽提塔液相进料口 21位于汽提塔 2 的侧边中上部, 汽提塔再沸蒸汽入口 23位于汽提塔加热介质进料口 21相对应的另一侧边中 下部, 汽提塔塔顶采出口 22位于汽提塔 2的顶部, 汽提塔塔釜出料口 24位于汽提塔 2的底 部; 汽提塔加热介质进料口 21与进料预热器出料口 12连接, 汽提塔塔顶采出口 22与压缩机 进料口 31连接, 汽提塔再沸蒸汽入口 23与汽提塔再沸器塔顶出料口 41连接, 汽提塔塔釜出 料口 24与汽提塔再沸器进料口 43连接, 汽提塔塔釜加热蒸汽补充口 25位于汽提塔塔釜, 与 外部加热蒸汽供应管道连接。
压缩机 3上设有压缩机进料口 31和压缩机出料口 32; 压缩机进料口 31与汽提塔塔顶采 出口 22连接, 压缩机出料口 32与汽提塔再沸器换热介质进料口 42连接。
汽提塔再沸器 4上设有汽提塔再沸器塔顶出料口 41、 汽提塔再沸器换热介质进料口 42、 汽提塔再沸器进料口 43、 汽提塔再沸器塔底出料口 44和汽提塔再沸器换热介质出料口 45, 汽提塔再沸器塔顶出料口 41位于汽提塔再沸器 4的顶部, 汽提塔再沸器塔底出料口 44位于 汽提塔再沸器 4的底部, 汽提塔再沸器进料口 43位于汽提塔再沸器 4的侧边, 汽提塔再沸器 换热介质进料口 42和汽提塔再沸器换热介质出料口 45位于汽提塔再沸器进料口 43相对应的 另一侧边的上部和下部; 汽提塔再沸器塔顶出料口 41与汽提塔再沸蒸汽入口 23连接, 汽提 塔再沸器换热介质进料口 42与压缩机出料口 32连接,汽提塔再沸器进料口 43与汽提塔塔釜 出料口 24连接, 汽提塔再沸器塔底出料口 44与进料预热器加热介质进料口 13连接, 汽提塔 再沸器换热介质出料口 45与精馏塔进料口 53连接。 精馏塔 5上设有精馏塔塔顶采出口 51、 精馏塔塔釜采出口 52和精馏塔进料口 53, 精馏 塔塔顶采出口 51位于精馏塔 5的顶部, 精馏塔塔釜采出口 52位于精馏塔 5的底部, 精馏塔 进料口 53位于精馏塔 5的侧边; 精馏塔进料口 53与汽提塔再沸器换热介质出料口 45连接。
上述的对实施例的描述是为便于该技术领域的普通技术人员能理解和应用本发明。 熟悉 本领域技术的人员显然可以容易地对这些实施例做出各种修改, 并把在此说明的一般原理应 用到其他实施例中而不必经过创造性的劳动。 因此, 本发明不限于这里的实施例, 本领域技 术人员根据本发明的揭示, 不脱离本发明范畴所做出的改进和修改都应该在本发明的保护范 围之内。

Claims

权 利 要 求 书
1. 一种低浓度有机溶剂水溶液回收热泵精馏装置, 其特征在于: 该装置包括进料预热器 (1)、 汽提塔 (2)、 压缩机 (3)、 汽提塔再沸器 (4) 和精馏塔 (5); 进料预热器 (1)、 汽提 塔 (2)、 压缩机 (3)、 汽提塔再沸器 (4) 和精馏塔 (5) 依次经过管路连接。
2. 根据权利要求 1所述的低浓度有机溶剂水溶液回收热泵精馏装置, 其特征在于: 所述 的进料预热器(1) 上设有进料预热器进料口 (11)、 进料预热器出料口 (12)、 进料预热器加 热介质进料口 (13) 和进料预热器加热介质出料口 (14), 进料预热器加热介质进料口 (13) 位于进料预热器(1) 的侧边, 进料预热器加热介质出料口 (14)位于进料预热器加热介质进 料口 (13) 相对应的另一侧边; 进料预热器出料口 (12) 与汽提塔液相进料口 (21) 连接, 进料预热器加热介质进料口 (13) 与汽提塔再沸器塔底出料口 (44) 连接, 进料预热器加热 介质出料口 (14) 位于进料预热器进料口 (11) 的下部。
3. 根据权利要求 1所述的低浓度有机溶剂水溶液回收热泵精馏装置, 其特征在于: 所述 的汽提塔(2)上设有汽提塔液相进料口 (21)、 汽提塔塔顶采出口 (22)、 汽提塔再沸蒸汽入 口 (23)、 汽提塔塔釜出料口 (24) 和汽提塔塔釜加热蒸汽补充口 (25), 汽提塔液相进料口
(21)位于汽提塔(2) 的侧边中上部, 汽提塔再沸蒸汽入口 (23)位于汽提塔加热介质进料 口 (21)相对应的另一侧边中下部, 汽提塔塔顶采出口 (22)位于汽提塔 (2) 的顶部, 汽提 塔塔釜出料口 (24)位于汽提塔(2) 的底部; 汽提塔加热介质进料口 (21)与进料预热器出 料口 (12) 连接, 汽提塔塔顶采出口 (22) 与压缩机进料口 (31) 连接, 汽提塔再沸蒸汽入 口 (23) 与汽提塔再沸器塔顶出料口 (41) 连接, 汽提塔塔釜出料口 (24) 与汽提塔再沸器 进料口 (43) 连接, 汽提塔塔釜加热蒸汽补充口 (25) 位于汽提塔塔釜, 与外部加热蒸汽供 应管道连接。
4. 根据权利要求 1所述的低浓度有机溶剂水溶液回收热泵精馏装置, 其特征在于: 所述 的压缩机 (3) 上设有压缩机进料口 (31) 和压缩机出料口 (32); 压缩机进料口 (31) 与汽 提塔塔顶采出口 (22) 连接, 压缩机出料口 (32) 与汽提塔再沸器换热介质进料口 (42) 连 接。
5. 根据权利要求 1所述的低浓度有机溶剂水溶液回收热泵精馏装置, 其特征在于: 所述 的汽提塔再沸器 (4) 上设有汽提塔再沸器塔顶出料口 (41)、 汽提塔再沸器换热介质进料口
(42)、 汽提塔再沸器进料口 (43)、 汽提塔再沸器塔底出料口 (44) 和汽提塔再沸器换热介 质出料口 (45), 汽提塔再沸器塔顶出料口 (41) 位于汽提塔再沸器 (4) 的顶部, 汽提塔再 沸器塔底出料口 (44)位于汽提塔再沸器(4) 的底部, 汽提塔再沸器进料口 (43)位于汽提 塔再沸器(4) 的侧边, 汽提塔再沸器换热介质进料口 (42)和汽提塔再沸器换热介质出料口
(45) 位于汽提塔再沸器进料口 (43) 相对应的另一侧边的上部和下部; 汽提塔再沸器塔顶 出料口 (41 ) 与汽提塔再沸蒸汽入口 (23 ) 连接, 汽提塔再沸器换热介质进料口 (42) 与压 缩机出料口 (32) 连接, 汽提塔再沸器进料口 (43 ) 与汽提塔塔釜出料口 (24) 连接, 汽提 塔再沸器塔底出料口 (44) 与进料预热器加热介质进料口 (13 ) 连接, 汽提塔再沸器换热介 质出料口 (45 ) 与精馏塔进料口 (53 ) 连接。
6. 根据权利要求 1所述的低浓度有机溶剂水溶液回收热泵精馏装置, 其特征在于: 所述 的精馏塔(5 )上设有精馏塔塔顶采出口(51 )、精馏塔塔釜采出口(52)和精馏塔进料口(53 ), 精馏塔塔顶采出口 (51 )位于精馏塔 (5 ) 的顶部, 精馏塔塔釜采出口 (52)位于精馏塔(5 ) 的底部, 精馏塔进料口 (53 )位于精馏塔 (5 ) 的侧边; 精馏塔进料口 (53 )与汽提塔再沸器 换热介质出料口 (45 ) 连接。
7. 权利要求 1~6任一所述的装置进行的低浓度有机溶剂水溶液回收热泵精馏工艺, 其特 征在于: 该工艺包括以下步骤:
首先将含有低浓度有机溶剂的水溶液通入进料预热器( 1 )中加热到泡点,通入汽提塔(2) 中进行提馏处理, 然后将汽提塔 (2) 塔顶采出的物料蒸汽通入压缩机 (3 ) 进行压缩后, 通 入汽提塔再沸器(4) 作为汽提塔再沸器(4) 的热源进行热换, 从汽提塔再沸器 (4) 出来的 冷凝物料作为精馏塔(5 )进料进行精馏工艺处理, 在精馏塔(5 )塔顶采出高浓度有机溶剂。
8. 根据权利要求 7所述的低浓度有机溶剂水溶液回收热泵精馏工艺, 其特征在于: 所述 的有机溶剂为能够与水互溶的一种或一种以上 〜 的有机化合物。
9. 根据权利要求 8所述的低浓度有机溶剂水溶液回收热泵精馏工艺, 其特征在于: 所述 的 ^〜 的有机化合物选自醇、 酮、 醛或酯类有机化合物, 例如: 甲醇、 乙醇、 正丙醇、 异 丙醇、 甲醛、 乙醛、 丙醛、 丙酮、 甲乙酮、 甲酸甲酯或甲酸乙酯。
10. 根据权利要求 7所述的低浓度有机溶剂水溶液回收热泵精馏工艺, 其特征在于: 所 述的低浓度有机溶剂是指有机溶剂在水中的质量浓度为 3~20%。
11. 根据权利要求 7所述的低浓度有机溶剂水溶液回收热泵精馏工艺, 其特征在于: 所 述的进料预热器、 汽提塔再沸器选自板式换热器、 管式换热器、 管板式换热器或者螺旋板式 换热器中的一种, 换热温差范围在 10~60°C。
12. 根据权利要求 7所述的低浓度有机溶剂水溶液回收热泵精馏工艺, 其特征在于: 所 述的压缩机 (3 ) 选自容积式压缩机, 往复式压缩机, 离心式压缩机中的一种, 升温范围在 20-60 °C , 压缩比为 1.5~4.0。
13. 根据权利要求 7所述的低浓度有机溶剂水溶液回收热泵精馏工艺, 其特征在于: 所 述的精馏塔(5 )选自筛板塔, 浮阀塔或者填料塔中的一种, 精馏塔的塔顶和塔釜的温差范围 为 20~45°C。
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